TIBRE Arable Handbook TIBRE Arable Handbook
Transcription
TIBRE Arable Handbook TIBRE Arable Handbook
52105_Inner_Cover 13/1/05 8:47 am Page 1 Scottish Natural Heritage is a government body responsible to the Scottish Executive Ministers, and through them to the Scottish Parliament. Our mission statement: Working with Scotland’s people to care for our natural heritage. Our aim: Scotland’s natural heritage is a local, national and global asset. We promote its care and improvement, its responsible enjoyment, its greater understanding and appreciation and its sustainable use now and for future generations. TIBRE Arable Handbook Our operating principles: We work in partnership, by co-operation, negotiation and consensus, where possible, with all relevant interests in Scotland: public, private and voluntary organisations, and individuals. We operate in a devolved manner, delegating decision-making to the local level within the organisation to encourage and assist SNH to be accessible, sensitive and responsive to local needs and circumstances. We operate in an open and accountable manner in all our activities. TIBRE Arable Handbook Further copies of this book are available from Scottish Natural Heritage Publications Section Battleby Redgorton Perth PH1 3EW t: 01738 444177 f: 01738 458613 e: pubs@snh.gov.uk w: www.snh.org.uk Copyright Scottish Natural Heritage 2004 ISBN 1 85397 416 1 TP1.5K1204 52105_Inner_Cover 13/1/05 8:47 am Page 2 Contents page Section 1 Section 2 Disclaimer 2 Acknowledgments 3 General Information Introduction 5 - 6 How to use the TIBRE Arable Handbook 7 - 8 Technologies and Products: The data sheets List of data sheets 9 General Management sheets 1-2 11 - 14 Crop Establishment sheets 3-5 15 - 20 Crop Nutrition sheets 6-16 21 - 42 Crop Protection sheets 17-40 43 - 96 Harvesting sheet 41 97 - 98 Making the Most of Technology Section 3 Section 4 99 - 100 Supplementary Information Products Under Development 101 - 102 Good Management Practices 103 - 104 Appendices Sources of Further Information 105 - 107 Acronyms 109 - 110 1 Disclaimer The technologies and products which are the subject of this updated version of the TIBRE Arable Handbook have been developed and marketed by their manufacturers. Further information about them is available from the manufacturers and their agents, farm advisers and consultants. Scottish Natural Heritage (SNH) is a Non-Departmental Public Body with no commercial interest in this field. It has obtained a wide range of specialist advice in reviewing and in compiling this Handbook. All reasonable efforts have been made to ensure the accuracy of the information given in the TIBRE Arable Handbook. SNH or any of its staff or agents cannot, however, be held responsible for any loss or damage which may be attributed to the use of any of the technologies, products or management practices to which the TIBRE Arable Handbook refers. The information given in this Handbook is not warranted and no responsibility can be accepted by SNH for any inaccuracies. Users of agricultural chemicals have a legal responsibility to read and understand the product label and to comply with current regulations. If the user is in any doubt about the nature, effect or use of any chemical or other technology or product they should clarify the position with either the manufacturer or their agents or otherwise obtain their own expert advice. 2 Acknowledgements Aidan Monaghan SOYL Ltd SNH wishes to thank all the people who provided Douglas Ogilvy Smiths Gore Ltd information and advice during the course of the review of the TIBRE Arable Handbook. John O’Rorke Scottish Quality Cereals The TIBRE Arable Group Farmers Mark Prentice British Potato Council Robert Balfour (SNH East Areas Board) Edward Baxter Geordie Burnett-Stuart Philip Chamberlain Peter Chapman (SNH Main Board) Bruce Cowe Alex Gordon Angus Jacobsen Brian Kaye Colin McGregor Michael Williams Doug Niven Norman Niven Willie Porter Gordon Rennie John Rymer Bill Taylor John Weir Allen Scobie Scottish Agronomy Ltd Dr Bruce Ball SAC Dr Rosie Bryson Velcourt Ltd Dr Ken Davies SAC Dr Andy Evans SAC Dr Steve Hoad SAC Dr Nigel Kerby SCRI Dr Rob Morris SEPA Dr Adrian Newton SCRI James Wyllie Dr Simon Oxley SAC Arable Advisers, Consultants and Others Richard Allan Robertson Crop Services Ltd Dr Philip Simons The Arable Group Gerald Banks Buchan Agricultural Consultants The review of the TIBRE Arable Handbook was carried out by Prof Paul Miller and Dr Ian Scotford of Silsoe Clive Christian Cleanacres Ltd Craig Herkes Crop Chemicals Ltd Jim Rennie Crop Chemicals Ltd Martin Johnston SEERAD J Neville Jones Neville Jones Crop Services David Kerr SAC Research Institute with contributions from Dr Jim Orson of The Arable Group. SNH would like to record special thanks to Dr Keith Dawson of SAC and Mr Tom Bals of Micron Sprayers Ltd. The TIBRE Arable Handbook was edited by Cécile Smith assisted by Scottish Natural Heritage colleagues Daniel Gotts, Claudia Rowse, Peter Pitkin and Hannah Levene. 3 4 section 1 General Information Introduction What is TIBRE? the TIBRE Arable Handbook. Some data sheets that were in the original TIBRE – Targeted Inputs for a Better Rural Environment – is an initiative by Scottish Natural Heritage which aims to show how technology can be used in farming to benefit the handbook were omitted because they were no longer considered relevant and similar benefits could be obtained by other more practical or reliable technologies. environment. environmentally responsible farming can be compatible with intensive available both in print and on the Internet at http://www.snh.org.uk/tibre methods and clear business objectives. Many new developments Environmental Management for Agriculture – In addition to being available on its dedicated web site, the TIBRE Arable Handbook is also included in interactive form within The TIBRE Arable Handbook is TIBRE aims to show that TIBRE and other initiatives the EMA – Environmental Management for Agriculture software and can be found in the EMA on-line library. In addition to a library, the EMA software contains decision The benefits of TIBRE support tools, data-bases, planning business performance of the farm The TIBRE Arable Handbook is an been developed to be used by can reduce the risk to the informed and practical tool for all farmers, advisers and consultants to environment that may result from involved in arable farming. It review environmental performance. farming. provides valuable information that is Although originally developed for not readily available in a collated England and Wales, it is now form anywhere else. available for Scotland and can in technology which will improve the The TIBRE – New options for arable farming handbook was first aids and audits for farm use and has provide Scottish farmers with a published in 1997 and provided The implementation of the range of environmental management information on 40 technologies and technologies and techniques tools relevant in Scottish farming. techniques including crop protection highlighted in the TIBRE Arable chemicals, machinery, information Handbook will help farmers: Integrated Farm Management – technology, fertilisers and crop • Protect the environment without The advice in the TIBRE Arable varieties. It was developed in close major changes to farm Handbook can help with consultation with a group of arable management implementing Integrated Farm Improve margins through better Management (IFM). IFM integrates management of inputs beneficial natural processes into Comply with environmental modern farming practices. It aims to standards while saving on costs reduce inputs such as fertilisers and farmers and advisers in Scotland. • The initiative received a very positive response from farmers, • advisers, consumer organisations and manufacturers. Over the last few years, there have been a variety of new technological • Gain access to quality markets and justify treatments to buyers and processors developments with the potential to help farmers achieve greater environmental standards and gain access to quality markets. As well as information on new ideas, developments and improvements of the original technologies have been incorporated in this new version of crop protection chemicals, enhance biodiversity, maintain soil fertility and minimise air, water and soil pollution. Methods used encompass a range of agronomic measures, The potential of these technologies and techniques will become greater as farmers are required to adhere to both cross compliance and the requirements of legislation implementing the EU Water Framework Directive. including crop rotation, appropriate cultivation techniques, careful choice of varieties and the use of predictive techniques. The TIBRE technologies and products can contribute to IFM 5 section 1 General Information procedures as they help: practices. The latter include • • • • diagnose diseases indicators for better practice in the apply crop chemicals judiciously use of technology and pesticides. In determine crop nutrient needs Crop Protection Management Plan match fertiliser application to infield variations in crop requirements • • addition, the Voluntary Initiative (CPMP) proposes the use of suitable technology as best environmental practice in a number of activities. improve waste management Here, the TIBRE Arable Handbook reduce contamination of non- provides a useful source of cropped areas and water courses additional information for farmers when drawing up a CPMP and In the UK, LEAF (Linking Environment and Farming) encourages farmers to adopt Integrated Farm Management. LEAF produces a range of technical information and demonstrates the principles of IFM on a network of 6 volunteer demonstration farms. LEAF members can benchmark their business against standards set in the LEAF Audit. In addition, they can apply to join the LEAF Marque certification scheme. For these farmers who have joined LEAF, the TIBRE Arable Handbook provides a useful reference to help achieve targets for action set in the LEAF Audit. The Voluntary Initiative – The adoption of new technology can help with the implementation of the Voluntary Initiative (VI). Farmers, advisers and manufacturers are urged to embrace the Voluntary Initiative, a programme of measures put forward by the industry to reduce the adverse environmental impacts from the use of pesticides and avert a pesticide tax. Targets have been set for a range of indicators covering water quality, biodiversity and changes in identifying priorities for action. The Voluntary Initiative also publishes Environmental Information Sheets (EIS) which provide information on the environmental impacts of crop protection products. Referencing a product’s label and its EIS to the local conditions at the application site can help improve product use decisions. The careful use of pesticides in combination with the adoption of improved application techniques will reduce the environmental impact of crop protection products both within the crop and on the wider countryside. section 1 General Information How to use the TIBRE Arable Handbook The Handbook aims to be practical Within each section, you will find a business and most relevant to your to use. The most important part is set of data sheets on different types environmental objectives. For section 2, which contains the data of technologies ranging from example, if your farm is in a Nitrate sheets. These highlight 41 machinery or diagnostic equipment Vulnerable Zone (NVZ), you may techniques and products with the to ways of using IT and mobile wish to concentrate on the information grouped under the communications. Each data sheet technologies that help minimise headings of the main arable provides information about a product potential nitrate leaching losses. operations – including Crop or a technology and its benefits for Establishment, Crop Nutrition, Crop both your business and the The general layout of the data Protection and Harvesting, as well as environment. The information will sheets is as shown below: a section on General Management. enable you to choose those aspects that are most suitable to your Caution Whenever relevant, alerts you to any potential risk to your business or to the environment that you need to be aware of when installing or using the technology. How can it help you? Outlines the benefits that the technology can bring to the farm business What is it? Explains what the technology is and describes its main features Name of technology or technique How can it help the environment? Outlines the potential environmental benefits of the technology Arable Operation Sheet number Crop Establishment Minimum Tillage Minimum Tillage Minimum tillage involves reducing cultivation depth and can avoid the use of the plough. The technique enables cheaper and quicker establishment and is predominantly used for winter cereals and winter oilseed rape. The approach can involve a number of techniques including direct drilling, broadcasting into existing stubbles or adopting a strategy of reduced tillage. Caution: Minimum tillage expected in your area. Establishing methods can sometimes result in crops early in the autumn poor establishment and increased (particularly oilseed rape) may input costs. For example, there present the best opportunity for can be an increase in slug activity using minimum tillage under suitable resulting from increased trash on soil moisture conditions in Scotland. the soil surface. An increase in Therefore there may be less benefit grass weeds, such as bromes and from using minimum tillage meadow-grasses, can also lead to techniques on farms in high rainfall increased herbicide use. In areas that have a large area of root addition, non-inversion tillage has crops. the speed of development of • The gross margins for combinable Eases management and workload crops have fallen and farm sizes in autumn have increased with fewer farm Helps achieve optimum drilling workers being employed. This has dates prompted interest in minimum tillage How can it help the environment? • • • Soil texture and structure are the circumstances main factors that influence Potential to increase soil for carabid beetles component in the decision making extra problems with cleavers and Often broad-leaved herbicide is not thistles. of soil necessary. The technique is probably not appropriate for the whole farm but there are instances (oilseed rape, first wheats required after peas) where it could difficult in Scotland for later • Sometimes poor spreading of chaff What is the current cultivation • Further information HGCA Topic Sheet 59 19 20 What is the objective of any change? How much will it cost you? Can the current system be Capital cost Large investment may be required Operating cost Potential to reduce establishment costs due ££ improved with little investment? • What is the current type of to more efficient use of labour and machinery. machinery, is it due for This may be offset by higher variable costs replacement soon? • establishment techniques? • e.g. herbicide Cost benefits __ What are the consequences of any change for fixed costs? leaching in some circumstances, e.g. by virtue of increased organic matter meadow-grass and sterile brome can A recent survey has indicated the make fields unsuitable for non- advantages and disadvantages of inversion tillage. Ploughing will be establishing oilseed rape by using a necessary on a rotational basis if novel system that sows the rape as root crops are included in the the previous cereal crop is rotation and this will help to reduce harvested. The system comprises a the grass weed burden. seed hopper and spreader that is fixed behind the combine header. It is also important to consider Optimum soil conditions have been whether minimum tillage techniques shown to be important of the will work given the levels of rainfall success of this broadcast technique. AICC HGCA Rothamsted Research SAC SCRI Soil Management Initiative • • • Novel Seed Treatments • Mechanical Weed Control process. The presence of rough Reduced pesticide and nitrogen AIC Technology links Potential increase in margins compared with ploughing • • • • • • • _ How much knowledge is there among farm staff of different cereal crops. results in patchy establishment. Are the soil, rainfall patterns and cropping system suitable? • cultivation method but weed problems are also an important techniques than in drilled crops. system and cost per hectare? drills) are now widely available. Reduced soil erosion in some weeds competing with crops. Some technique has proved to be • Reduced use of fossil fuels biodiversity, e.g. improved habitat • equipment, presses and cultivator move the minimum amount established using broadcasting work. In wet autumns this cultivation methods and suitable machines (e.g. disc/tine cultivation to re-establish drainage and drainage. cereal diseases. higher work rates Extra time to learn the system and for post-sowing management Prolific volunteer cereals and grass capped or compacted soil with poor • • Cheaper, quicker establishment Fewer broad-leaved weeds in crops often made travelling easier should be asked: Reduced establishment time – ground after any cultivation Establishment may be poor in and resistance to fungicides in Availability and use Disadvantages Use of tramlines from previous crop cultivation methods the following resulting in reduced cost Technical tip Always consolidate the Advantages Before considering minimum tillage resistance to herbicides in weeds • Advantages and disadvantages of broadcast establishment of oilseed rape been associated with increasing How can it help you? Potentially reduced passes 5 Crop Establishment section 2 Crop Establishment What is it? Technical Tip Outlines a pertinent technical point How much will it cost you? Indicates the scale of costs and benefits of the technology 5 Crop Establishment section 2 Further Information Suggests a range of organisations or publications that can give further information about the technology Availability and Use Indicates which products are currently on the market and how easy it will be to use the technology Co-ordinated Slug Control Appropriate Active Ingredient Use Technology links Lists other related technologies in the Handbook 7 section 1 General Information How to use the TIBRE Arable Handbook 8 Note that the information provided that interest you and adopt them. For any product, it is important to in How much will it cost you? aims Each product and technology can follow good practice to achieve full to give a general indication of the independently deliver benefits to farming and environmental benefit. scale of costs and benefits farming practices and provide an New technology on its own associated with the purchase and improved level of environmental cannot replace careful use. the implementation of the protection. However, if you are technology or product. It does not prepared to go beyond these simple You may also wish to consider provide a tool for comparing choices, you will be able to make implementing some of the ideas different technologies and products. more and better use of the available described in the section Good The symbols used do not represent technology by planning your management practices to enhance equivalent numerical values: for approach more thoroughly. Give the environmental benefits from the example a low to medium cost careful thought to your current farm use of the TIBRE products and capital investment cannot be management and the scope for technologies and help support compared to a low to medium improvement from both the business farmland wildlife. operating cost. and environmental point of view. We recommend that you consult an If you have any comments on the You can use the Handbook in several adviser before adopting the TIBRE Arable Handbook, please get ways. At the simplest level, you technologies and products contained in touch with us at tibre@snh.gov.uk could browse through the data in the Handbook. sheets, choose one or two products Symbols Capital and operating costs Cost:Benefits - No increase in cost Neutral £ Low to medium costs Low net costs ££ High to very high costs High net costs Small savings Low net benefits Significant savings High net benefits section 2 Technologies and Products List of data sheets General Management 21 Improved Formulation and Packaging 1 Electronic Communication 22 Appropriate Active Ingredient Use 2 Internet Information, 23 Appropriate Herbicide Use 24 Appropriate Fungicide Use 25 Appropriate Insecticide Use 26 Pesticide Mixtures 27 Pesticide Handling Systems 28 Sprayer Control and Maintenance 29 Patch Spraying 30 Appropriate Spray Quality 31 Drift Reduction by Nozzle Selection 32 Air-Assisted Spraying Application 33 Air Induction Nozzles 10 Improved Fertiliser Spreading Characteristics 34 Twin Fluid Nozzles 11 Improved Targeting of Fertiliser Close to 35 Rotary Atomisers 36 Low Volume Spraying 37 Low Volume Washing Systems 38 Sprayer Decontamination 39 Weed Wipers 40 Mechanical Weed Control Prediction Schemes and Tools Crop Establishment 3 Variety Choice 4 Novel Seed Treatments 5 Minimum Tillage Crop Nutrition 6 Fertiliser Planning 7 Nitrogen Diagnostic Technology 8 Targeted Nitrogen Application 9 Targeted Phosphate, Potash and Lime Field Boundaries 12 Boom Fertiliser Spreaders 13 Manure-Value Diagnostics 14 Improved Manure Storage 15 Improved Manure Application 16 Precision Irrigation Crop Protection 17 Crop Diagnostics 18 Monitoring Pest Activity 19 Decision Support Systems 20 Co-ordinated Slug Control 9 Harvesting 41 Yield Mapping Making the Most of Technology Making the Most of Technology section 2 10 Technologies and Products 1 General Management section 2 General Management Electronic Communication What is it? With reducing staff numbers and How can it help the environment? increasing complexity of the farm • business, good communication and up-to-date information is critical. • wealth of information for the farmer and adviser. See the Reduced amounts of pesticides in TIBRE data sheet Internet the environment • information, prediction schemes Reduced groundwater and surface Electronic communication covers a water pollution resulting from wide range of technologies from improved timing and targeting of citizens band radio and mobile inputs Internet – the Internet provides a and tools. • e-mail – used to send and receive information e.g. agronomic recommendations, weather phones to computers and the Availability and use information, crop alerts, improve the quality of decision An increasing number of electronic analysis reports. making. Many of the technologies in communication devices are coming the TIBRE Arable Handbook rely on onto the market every day, each devices, which can be used to electronic communication to be most being more user-friendly, as well as make notes while field walking or effective (see Technology links increasing in durability and carrying out other operations. On below). electronic complexity over its returning to the farm office the predecessor. Some devices are listed information can be downloaded below, but many others are also and used to update farm records available. and data. Internet. They all help to increase the speed of communication and How can it help you? • • • • • Improved timing and work planning • • agronomy bulletins and soil • Mobile communication – citizens Improved decision making band radio for on-farm or local Avoidance of unnecessary communication and mobile applications of fertiliser and phones many of which now offer pesticides facilities for sending pictures. Improved training efficiency • • Hand-held loggers – electronic Rate control systems – designed for accurate application of pesticides and fertiliser. They can be used with Global Positioning Systems (GPS) to enable the right treatment to be applied in the Messaging services – several right place at the right time. through use of distance learning companies offer to send the latest Digitised input plans can be methods via web based resources information to your mobile phone, downloaded to machinery e.g. via Improved record keeping e.g. weather forecasts, or potato smart cards. Such systems can be blight information in your area. used throughout the year in an Computers – an essential part of integrated approach to control the farm office, used for record many farming operations. Better use of limited staff resources • keeping, data recording, Internet, e-mail, decision support systems and other operations. 11 1 General Management section 2 General Management Electronic Communication Technical tip There are many types of electronic communication equipment produced and sold by many different manufacturers, often to their own individual standards, which may not be compatible with other manufacturers. Ensure all the communication equipment you select is fully compatible. Silsoe Research Institute 12 Further information • Local high street phone stores • Computer shops and magazines • • • • • • Popular farming press Electronic communication can be used to integrate the farming approach and improve many farming operations How much will it cost you? Capital cost Operating cost Cost benefits Mobile communication, e.g. mobile phones and citizens band radio £ Computer ££ Hand held logger £ Rate control systems ££ Contract or call charges for mobile phones £ Charges for messaging service £ Internet provider £ AIC AICC HGCA SAC Technology links • Internet Information, Prediction Schemes and Tools • • Fertiliser Planning • Targeted Nitrogen Application • Targeted Phosphate, Potash and Lime Application • • • • • Manure-Value Diagnostics Using electronic communication to integrate the farming approach can improve the AEA efficiency of many operations Nitrogen Diagnostic Technology Monitoring Pest Activity Decision Support Systems Patch Spraying Yield Mapping 2 General Management section 2 General Management Internet Information, Prediction Schemes and Tools What are they? Availability and use The Internet (or World Wide Web) The list of information and tools to contains a vast amount of be found on the Internet is information that can be useful to extensive. Below is a list of the you. This useful data source can be types of information that are accessed from a personal computer available. • select the most suitable nozzle type for the crop protection product you plan to use, its mode of action, the target pest, weed or disease type and the crop or weed growth stage. which is connected via a service provider to the Internet, either using Nozzle selection – allows you to • Weather information – provide • General information – most a dial-up service or Broadband link. detailed weather information on a organisations now have web sites There are now many sites on the regional basis and offer forecasts that contain information on their Internet specifically designed to up to 15 days ahead. activities. provide information and advice to • Disease trackers – indicate the farmers and advisers on a range risk of crop disease on a regional The information on the Internet is of topics. basis. constantly being updated; use it How can they help you? • • Pest trackers – indicate the risk of crop pest on a regional basis. • compare varieties of your choice decision making from the latest recommended Improved timing and work lists. • Offers potential for reduced inputs Fertiliser calculators – help you to optimise fertiliser rates and reduce the risk of losses into the How can they help the environment? • Reduced amounts of pesticides in the environment • wider environment. • Seed rate calculators – estimate the seed rate needed to achieve a desired crop establishment based on seed germination, expected Reduced groundwater and surface water pollution resulting from improved timing and targeting of inputs regularly to obtain the latest information available. Variety selectors – help you Improved risk analysis and planning • • establishment, required plant population and Thousand Seed Weight. 13 2 General Management section 2 General Management Internet Information, Prediction Schemes and Tools How much will it cost you? Capital cost Computer Operating cost Internet provider and access to individual ££ web sites Cost benefits £ Improved management offers the potential for reduced inputs Technical tip Use search engines to find Further information Search Engines sites that provide information weather data, potato blight, Other sites of interest include: • AEA (www.aea.uk.com) seed rates). Beware that • AIC (www.agindustries.org.uk) • • • AICC (www.aicc.org.uk) • • • BCPC (www.bcpc.org) • • DEFRA (www.defra.gov.uk) • • HGCA (www.hgca.com) • Pesticide Forum (www.pesticides.gov.uk/ pesticides-forum) • • PSD (www.pesticides.gov.uk) on a particular subject (e.g. some manufacturers’ web 14 sites may only provide partial information. Always compare data on several sites to obtain a more comprehensive understanding of the subject. BASIS (www.basis-reg.co.uk) BBC Weather Forecast (www.bbc.co.uk/weather) • • • SASA (www.sasa.gov.uk) • • SNH (www.snh.org.uk) • Voluntary Initiative (www.voluntaryinitiative.org. uk) • Weather Channel (uk.weather.com) BPC (www.potato.org.uk) SCRI (www.scri.sari.ac.uk) SEERAD (www.scotland.gov.uk/agri) UK FWAG – Scottish Site (www.fwag.org.uk/scotland) CPA (www.cropprotection.org.uk) Farmers Weekly (www.fwi.co.uk) Met Office (www.metoffice.co.uk) SAC (www.sac.ac.uk) Technology links • • • • • • Electronic Communication Fertiliser Planning Precision Irrigation Crop Diagnostics Monitoring Pest Activity Decision Support Systems 3 Crop Establishment section 2 Crop Establishment Variety Choice What is it? Availability and use A crop’s agronomic and quality Experiments have shown that characteristics, as well its resistance significant savings can be made in to diseases and insect pests are pesticide use in the more resistant genetically determined and vary and disease-tolerant crop varieties. widely between varieties. Variety Such varieties are widely available choice depends on many factors, but and their uptake by farmers is often the two main criteria are determined by whether they can meeting market requirements and meet market requirements. There yield. However, it is often possible to may be yield penalties associated choose varieties with inherently with resistant varieties, but cost better resistance to insect pests and savings on inputs can often offset diseases that can still meet market the reduced income from a lower requirements. This can reduce yield. There are a number of ways in pesticide use and enable a more which you can exploit varietal flexible approach to management, resistance or tolerance to disease in which can be particularly valuable your variety choice, and below are where labour and machinery just some examples: rotations. Potato varieties showing improved resistance to • number of suitable spraying days. Reduced pesticide use leading to reduced costs and a delay in the • • The use of the Mlo gene in that this can prove to be impractical as different maturity and grain specifications can complicate harvest and marketing. Generally, it is only suitable for cereals used for feed, although recent work by SCRI on blends for malting markets has shown some promise. Recent work has also shown that cereal resistance management. control. selection. For example Riband and Some disease tolerant varieties of applications. This is particularly Increased flexibility of useful in fields that are a long way from the steading. • cereals, although resistance or How can it help the environment? tolerance of barley yellow dwarf • barley variety selection. virus (BYDV), which is spread by aphids, is an important factor for Reduced amount of pesticides in • Consort, which are grown for the distilling market in Scotland, have inherently poor resistance to Septoria tritici (see table below). Trials data from Scotland and elsewhere in the UK suggest that fungicide costs in these varieties can Varietal resistance is not so successful for insect control to high disease resistance • resistance within the crop. Note driving force behind variety two rather than three fungicide the environment to improve overall disease reducing the costs of mildew resistance to pesticides apply fungicides to varieties with mixtures, particularly with cereals Market forces are generally the winter wheat may only require A larger time window in which to Blends of varieties can be used as has been very successful in development of pest or disease management • • malting spring barley varieties How can it help you? • available e.g. Lady Balfour blends can aid fungicide resources are limited or where weather conditions restrict the potato blight are also becoming be £15-£20/ha higher than in varieties with higher levels of resistance to the disease and that the timing of fungicide application is also more critical. On the other hand, the winter barley variety Pearl has been accepted for malting and Certain varieties of potato are offers inherently better disease Reduced energy use, e.g. reduced relatively resistant to Potato Cyst resistance than some older winter applications of pesticides Nematode (e.g. M Piper, Ro1) or barley malting varieties, although its slug attack (e.g. P Dell, L quality is sometimes poorer in Rosetta). These are important Scotland. factors to consider in planning 15 3 Crop Establishment section 2 Crop Establishment Variety Choice 2004 UK recommended list of winter wheat varieties: comparative Technical tip disease resistance Potato varieties with Resistance to disease Claire Consort Malacca Hereward Riband resistance to potato cyst nematode are useful as part Mildew 4 6 7 5 6 of an integrated control Yellow rust 9 5 9 5 6 programme, decreasing the Brown rust 8 4 7 6 3 Septoria 7 5 7 7 4 Septoria tritici 6 4 5 6 3 Eyespot 6 7 3 5 6 Fusarium 7 6 6 5 6 need for soil applied nematicides. nodorum ear blight Further information • HGCA recommended lists for cereals and oilseeds • PGRO recommended lists for peas and beans • BPC recommended lists for potatoes • NIAB recommended lists for pulses and other crops • SAC recommended lists for cereals and pulses • • • • • Breeder’s information Data from the HGCA Recommended List 2004/05, full database at http://www.hgca.com Note: The higher the number, the more resistant the variety is to the disease. 16 Quality, yield and disease and insect pest resistance are not the only factors to consider when selecting varieties to be grown. Time of sowing, resistance to lodging, maturity date, ear loss and sprouting risk are just some other factors to take into account when selecting varieties. These factors are increasingly important when planning crop management requirements for the whole crop cycle now that many farms have significantly reduced labour and machinery availability. How much will it cost you? Capital cost No capital investment required Operating cost No appreciable increase in price of seed - over other bought-in varieties. Newer varieties often command a small price premium. Cost benefits Savings can be made by reduced pesticide usage in addition to reduced cost of labour and machinery Note: There may be cost implications for home savers who use older varieties with no BSPB royalties to pay (e.g. Riband and Pastoral). £ AIC AICC BSPB SCRI Technology links • • • • Novel Seed Treatments Crop Diagnostics Monitoring Pest Activity Appropriate Fungicide Use 4 Crop Establishment section 2 Crop Establishment Novel Seed Treatments What are they? Availability and use Dressings can be applied to seed to These seed dressings are widely control insect pests and soil-borne or available when purchasing certified foliage diseases in cereals and other seed. They are also available to crops. They have been used for contractors who dress seed on-farm. many years, but the introduction of Products include: shown there are acceptably low infestations of the target diseases. newer novel treatments has widened their scope. Some will help avoid the • avoid or reduce the use of that may have greater insecticide sprays. These may environmental impact. have an overall benefit to the environment, e.g. seed • • wheat bulb fly, barley yellow dwarf virus (BYDV) in early drilled cereals with imadocloparid. Potential for improved insect pest and disease control • • • • treatments for the control of Improved yield diagnostic technologies that allow rapid testing of seed. Yield responses to the use of silthiofam seed dressing for take-all Seed treatments that help to use of post-emergence treatments How can they help you? This has been made possible by new control in winter wheat have been around 0.5t/ha in Scotland and in England where crops are grown in high risk situations. This average hides a large variation in yield response despite a risk assessment based on field history, place in rotation, level of inoculum, soil structure, pH and phosphate status. This is because weather conditions • Seed treatments that increase the over the winter and spring (i.e. after modes of action available for the sowing) determine the rate of Alternatives to insecticide sprays control of a particular pest (e.g. development of the disease. It has Ease of management aphid as vectors of BYDV in also been shown in trials that the cereals), hence reducing the risk seed treatment supplements, of resistance developing complements rather than replaces, Longer term insecticide protection Improved pesticide resistance management strategies cultural control of take-all. How can they help the environment? • • Seed treatments can also indirectly reduce environmental impacts, for example take-all seed treatments Reduced amounts of pesticides in help reduce nitrate leaching which the environment would otherwise occur due to poor Less insecticide use in autumn in rooting in affected crops. areas at high risk from insect pests More cereal seed can now be used that has not been treated with Caution: Some products are toxic fungicides for the control of seedling to birds and good seed coverage diseases, provided that tests have is essential. Personal Protection Equipment (PPE) may be required when handling seed. The seed is often sown before the precise level of threat from the target can be quantified and so a proper risk analysis needs to be carried out before treated seed is ordered and used. 17 4 Crop Establishment section 2 Crop Establishment Novel Seed Treatments How much will it cost you? Technical tip - Capital cost No capital investment required Operating cost Seed treatments may cost more than risk assessment before using the equivalent spray treatment novel seed treatments. Seed (where the two options are available) £ It is important to carry out a treatments should be viewed as complementing rather Cost benefits Improved margins may be achieved along with the advantage of easier management than replacing cultural control, as their use for all seed would prove prohibitively expensive and could have adverse environmental effects. Further information 18 • • • • • AIC AICC HGCA SAC SCRI Technology links • • • • • • • Variety Choice Minimum tillage Crop Diagnostics Monitoring Pest Activity Decision Support Systems Appropriate Fungicide Use Appropriate Insecticide Use 5 Crop Establishment section 2 Crop Establishment Minimum Tillage What is it? Minimum tillage involves reducing cultivation depth and can avoid the use of the plough. The technique enables cheaper and quicker establishment and is predominantly used for winter cereals and winter oilseed rape. The approach can involve a number of techniques including direct drilling, broadcasting into existing stubbles or adopting a strategy of reduced tillage. Caution: Minimum tillage expected in your area. Establishing methods can sometimes result in crops early in the autumn poor establishment and increased (particularly oilseed rape) may input costs. For example, there present the best opportunity for can be an increase in slug activity using minimum tillage under suitable resulting from increased trash on soil moisture conditions in Scotland. the soil surface. An increase in Therefore, there may be less benefit grass weeds, such as bromes and from using minimum tillage meadow-grasses, can also lead to techniques on farms in high rainfall increased herbicide use. In areas that have a large area of root addition, non-inversion tillage has crops. been associated with increasing the speed of development of Before considering minimum tillage How can it help you? resistance to herbicides in weeds cultivation methods the following and resistance to fungicides in should be asked: • cereal diseases. Potentially reduced passes resulting in reduced cost • • • Reduced establishment time – Availability and use higher work rates The gross margins for combinable Eases management and workload crops have fallen and farm sizes in autumn have increased with fewer farm Helps achieve optimum drilling workers being employed. This has dates prompted interest in minimum tillage • system and cost per hectare? • How can it help the environment? • • • • • Soil texture and structure are the circumstances main factors that influence Potential to increase soil • for carabid beetles component in the decision-making What is the current type of machinery – is it due for replacement soon? • How much knowledge is there among farm staff of different establishment techniques? cultivation method, but weed problems are also an important Can the current system be improved with little investment? drills) are now widely available. Reduced soil erosion in some What is the objective of any change? Reduced use of fossil fuels biodiversity, e.g. improved habitat • equipment, presses and cultivator Are the soil, rainfall patterns and cropping system suitable? cultivation methods and suitable machines (e.g. disc/tine cultivation What is the current cultivation • What are the consequences of any change for fixed costs? process. The presence of rough Reduced pesticide and nitrogen leaching in some circumstances, e.g. by virtue of increased organic matter meadow-grass and sterile brome can A recent survey has indicated the make fields unsuitable for non- advantages and disadvantages of inversion tillage. Ploughing will be establishing oilseed rape by using a necessary on a rotational basis if novel system that sows the rape as root crops are included in the the previous cereal crop is rotation and this will help to reduce harvested. The system comprises a the grass weed burden. seed hopper and spreader that is fixed behind the combine header. It is also important to consider Optimum soil conditions have been whether minimum tillage techniques shown to be important to the will work given the levels of rainfall success of this broadcast technique. 19 5 Crop Establishment section 2 Crop Establishment Minimum Tillage Advantages and disadvantages of broadcast establishment of oilseed rape Technical tip Always consolidate the Advantages Disadvantages Cheaper, quicker establishment Extra time to learn the system and to re-establish drainage and for post-sowing management move the minimum amount ground after any cultivation Fewer broad-leaved weeds in crops Prolific volunteer cereals and grass established using broadcasting weeds competing with crops. Some techniques than in drilled crops. extra problems with cleavers and Often broad-leaved herbicide is not thistles. of soil necessary. The technique is probably not appropriate for the whole farm but there are instances (oilseed rape, first wheats required after peas) where it could Use of tramlines from previous crop Establishment may be poor in work. In wet autumns this often makes fieldwork easier capped or compacted soil with poor technique has proved to be drainage. difficult in Scotland for later Sometimes poor spreading of chaff cereal crops. results in patchy establishment. Further information HGCA Topic Sheet 59 20 How much will it cost you? Capital cost Large investment may be required Operating cost Potential to reduce establishment costs due ££ to more efficient use of labour and machinery. This may be offset by higher variable costs e.g. herbicide Cost benefits Potential increase in margins compared with ploughing - • • • • • • • AIC AICC HGCA Rothamsted Research SAC SCRI Soil Management Initiative Technology links • • • Novel Seed Treatments • Mechanical Weed Control Co-ordinated Slug Control Appropriate Active Ingredient Use 6 Crop Nutrition section 2 Crop Nutrition Fertiliser Planning What is it? Fertiliser planning is an important part of crop production. Fertiliser • based on environmental factors week in Farmers Weekly for the and previous cropping regimes. first few months of the year and MANNER – is a computer program is also available on the Internet. that assesses the fate of nitrogen management programs aim to following application of manure reinforce best practice. They can aid based on manure type, soil type, decisions on fertiliser application method and timing of recommendations, timing and rate of • • • • SCRI fertiliser models. Fertiliser and manure application models are available on the latest application. application, using a given set of SAC manure models. edition of the EMA (Environmental TSum – is a measure of the Management for Agriculture) crop data, weather data, etc.) which cumulative air temperature over software from the University of are based on the specific conditions time, beginning in January. Hertfordshire. found on your farm or in your field. Dependant upon ground and crop information inputs (e.g. soil data, condition, the first application of How can it help you? • • distributors and suppliers also nitrogen for grass should be have computer based fertiliser applied when TSum reaches 200. Improved nutrient utilisation Many fertiliser manufacturers, programs available. A TSum map is printed every resulting in improved gross margins • Improved timing and targeting of inputs • Help comply with rules in nitrate vulnerable zones (NVZs) Example of a TSum map, used for determining optimum timing for nitrogen applications to grass crops (20 February, 2003) 005 001 006 007 008 009 010 011 012 013 014 015 How can it help the environment? • • 21 002 003 004 133 016 017 018 019 020 021 022 023 024 025 026 027 028 Reduced build up of nutrients in the soil above the levels needed 029 030 031 032 033 034 for optimum production 035 036 037 038 039 040 Reduced atmospheric pollution 041 042 043 044 045 046 from excess application of • nitrogen fertilisers 127 128 129 047 048 049 050 051 Reduced groundwater and surface 130 131 132 052 053 054 055 056 057 058 059 060 061 062 water pollution from nitrate leaching and phosphate run off 063 064 065 066 067 T-Sum forecast by 27/2/2003 Availability and use Many fertiliser programs are 068 069 070 071 072 073 074 T-Sum forecast by 9/3/2003 075 076 077 078 079 080 081 082 083 T-Sum forecast by 19/3/2003 available; the list below shows some examples. 084 085 086 087 088 089 090 091 T-Sum forecast after 19/3/2003 • SUNDIAL – is a computer 102 103 104 105 106 107 108 109 program that assesses the 110 111 112 113 114 115 116 117 118 nitrogen requirements of fields 119 120 121 122 123 124 125 126 Farmers Weekly 092 093 094 095 096 097 098 099 100 101 6 Crop Nutrition section 2 Crop Nutrition Fertiliser Planning How much will it cost you? Capital cost some computer programs Operating cost £ Unlikely to be increased operating costs compared with standard practice Cost benefits Technical tip There may be a small cost associated with Improved fertiliser planning can reduce fertiliser costs - Fertiliser planning programs are often tailored to given climatic conditions. Ensure that the plan you are using is suitable for your given application. In addition, these plans often require a series of inputs, e.g. soil data, crop data and weather data. Always use the best data available - poor data can result in poor recommendations. Further information • • 22 • • • • • • • Farmers Weekly web site (www.fwi.co.uk) EMA software. University of Hertfordshire Fertiliser Recommendations for Agricultural and Horticultural Crops (RB 209). MAFF Guidelines for farmers in NVZs. Scottish Executive P and K fertiliser planning, using soil and plant analysis to plan fertiliser use. Autumn 2000. HGCA AIC AICC FACTS qualified adviser SAC Technical fertiliser notes Technology links • • • • • • • • Electronic Communication Internet Information, Prediction Schemes and Tools Nitrogen Diagnostic Technology Targeted Nitrogen Application Targeted Phosphate, Potash and Lime Application Manure-Value Diagnostics Decision Support Systems Yield Mapping 7 Crop Nutrition section 2 Crop Nutrition Nitrogen Diagnostic Technology What is it? This technology aims to maximise the efficient use of nitrogen by matching application rate to the in. Other tests such as the N-min For these techniques careful tool take soil cores and the sampling is required to ensure the estimate from this is fed into a soil or leaf samples are point system related to yield representative. potential and crop nitrogen specific needs of the crop. This can requirement. help to reduce over application of nitrogen, which results in economic Satellite, aerial or vehicle mounted sensors, measuring the spectral Indirect measurements via a plant characteristics of the crop canopy, value such as chlorophyll content can also be used to assess crop or tissue analysis: for example, condition from which nitrogen inputs How can it help you? chlorophyll testers are used to can be determined. Several estimate the amount of commercial companies offer this • Improved nitrogen utilisation chlorophyll in individual leaves service. Field maps produced by resulting in improved gross which can then be related to the these techniques can now be linked margins N requirements of the crop. into soil and yield maps. Improvements in yield and Nitrate test strips can also be quality, particularly in malting used in the field to give an Caution: Nitrogen is a key driver barley and breadmaking wheat approximate guide to N status. of yield and great care must be losses and increased risk of nitrate leaching. • • Reduced risk of lodging in cereals How can it help the environment? • taken in targeting rates correctly. Growth regulator use may also be linked to nitrogen application rate. Reduced watercourse and groundwater pollution from nitrate leaching Reduced atmospheric pollution Chlorophyll testers are small hand held devices that can be used to determine the leaf chlorophyll content and help to determine subsequent nitrogen application from excess application of nitrogen fertiliser Yara UK Ltd • • Availability and use Several nitrogen diagnostic techniques are available: • Direct measurements of soil Silsoe Research Institute available nitrogen using simple tests: an example is the Solomon system that uses portable field equipment to determine nitrate concentrations in soil, plant-sap and water in arable crops. Reagent strips are placed in a reflectometer to give a nitrate reading after the sample is dipped Prototype tractor mounted sensors used to assess canopy condition to help determine nitrogen requirements 23 7 Crop Nutrition section 2 Crop Nutrition Nitrogen Diagnostic Technology How much will it cost you? Capital cost Operating cost Chlorophyll testers £ Vehicle mounted sensors ££ Increased operating costs for direct measurement of soil-N 24 Nitrogen diagnostic technology reinforces best practice, e.g. using fertiliser recommendations. Ensure ££ that your spreading Sensor derived maps will increase operating equipment is correctly costs either produced by yourself via vehicle calibrated and is able to mounted sensors or by a contractor using apply the nitrogen evenly and aerial or satellites Cost benefits Technical tip Although there is a cost associated with ££ at the correct rate. nitrogen diagnostics, better use of nitrogen Further information can result in improved gross margins • The Wheat Growth Guide, 1998. HGCA • Canopy management in winter wheat, Topic Sheet No. 40. Autumn 2000. HGCA • Precision farming of cereals, practical guidelines and crop nutrition, 2002. HGCA • Fertiliser Recommendations for Agricultural and Horticultural Crops (RB 209). MAFF • • • • • AICC AIC FACTS qualified adviser SAC Technical fertiliser notes The Precision Farming Alliance Technology links • • • Electronic Communication • • Boom Fertiliser Spreaders Fertiliser Planning Targeted Nitrogen Application Manure-Value Diagnostics 8 Crop Nutrition section 2 Crop Nutrition Targeted Nitrogen Application What is it? Availability and use Targeted nitrogen application aims Assess your in-field variability using to build on nitrogen techniques such as field walking, soil recommendations and nitrogen nitrogen measurement, chlorophyll diagnostic techniques. It uses testers or spectral characteristics of variable rate application technology crop canopy. Yield maps from to apply nitrogen to account for the previous seasons will also help in-field variability of the crop assess variability (see HGCA Topic nitrogen requirements. Sheet No. 70). If sufficient How can it help you? • variability is found, decide on which variable nitrogen strategy to use: • conditions. Use conventional Reduced variability in yield and application equipment to apply quality, particularly for nitrogen to each zone depending breadmaking wheat and malting • Use a treatment map, generated from nitrogen diagnostic How can it help the environment? techniques, and variably apply • Reduced groundwater and surface system and Global Positioning water pollution from nitrate Systems (GPS). Several GPS and leaching rate control systems are now Reduced atmospheric pollution available commercially. • available to measure canopy condition in real time – as you drive along spreading fertiliser. These can be used in conjunction with control systems to vary nitrogen applications in real time. The map below shows an example of the variability in crop density as measured using spectral reflectance used to variably apply nitrogen. The general philosophy is to increase nitrogen in areas of low crop density and decrease nitrogen in areas of high crop density. on its specific conditions. barley Reduced risk of lodging in cereals Zone field into management areas having similar soil or canopy margins • Commercial systems are also techniques. Such information can be Improved nitrogen utilisation resulting in improved gross • • nitrogen using a spreader or sprayer fitted with a rate control Caution: Nitrogen is a key driver of yield and great care must be taken in targeting rates correctly. Growth regulator use may also be linked to nitrogen application rate. from excess application of nitrogen fertiliser Variability in crop density identified using spectral reflectance techniques 25 Silsoe Research Institute 8 Crop Nutrition section 2 Crop Nutrition Targeted Nitrogen Application Caution: Care is required when interpreting these maps. It is important to check in the field to identify other possible causes of in-field variability. For example: • An area shown as having a high crop density may actually be a weed infested area rather than a thick crop. • Further information • • • FACTS qualified advisers • The Wheat Growth Guide, 1998. HGCA. • Precision farming of cereals, practical guidelines and crop nutrition, 2002. HGCA • • • • • • Technical fertiliser notes A low crop density may be an indication of pest damage or disease and hence would not benefit from increased nitrogen application without controlling the cause of the problem. In some circumstances, variable rate application of nitrogen has shown benefits of up to £22/ha compared to standard input programmes. (Source: Precision farming of cereals, practical guidelines and crop nutrition, Spring 2002. Home Grown Cereals Authority). How much will it cost you? Capital cost Operating cost Variable rate control systems ££ Sensing systems ££ Variable rate control systems: increased maintenance 26 £ Sensing systems: production of treatment maps Cost benefits £ Equipping machinery with a variable rate control systems is a significant cost. However the technology can also be used for varying other inputs, e.g. seed rates, herbicides, fungicides and growth regulators Technical tip Always apply nitrogen based on best practice; only consider using targeted nitrogen application if you have sufficient in-field variability to justify it. For example, assuming 20% of your farm responded to variable rate application you would need to have a yield increase on those areas of 0.95, 0.48, 0.32 and 0.24 (t/ha) for farmed areas of 250, 500, 750 and 1000 (ha) respectively to justify the cost of variable rate technology. Precision farming advisers Fertiliser Recommendations for Agricultural and Horticultural Crops (RB 209). MAFF AIC AICC SAC SCRI The Precision Farming Alliance Technology links • • • Electronic Communication • Targeted Phosphate, Potash and Lime Application • Improved Fertiliser Spreading Characteristics • Improved Targeting of Fertiliser Close to Field Boundaries • Boom Fertiliser Spreaders • Yield Mapping Fertiliser Planning Nitrogen Diagnostic Technology 9 Crop Nutrition section 2 Crop Nutrition Targeted Phosphate, Potash and Lime Application What is it? potash and pH levels have been Phosphate, potash and pH levels can vary significantly within a field due to differences in soil type, management history and nutrient offtake as harvested crop. High yielding areas will remove large amounts of nutrients, whereas low yielding areas built up or run down. Using Re-sampling commercial fields in Macaulay soil maps and field Scotland after five years of variable experience can aid the correct phosphate, potash and lime positioning of sampling points. application has shown very clear Generally an average of 1 evidence of reducing the proportion sample/ha is needed; in most of the field with low and high circumstances it is not economic nutrient levels. This reduced soil to sample more intensively. nutrient variability has resulted in remove only small amounts. Targeted application aims to maintain uniform levels of yield and quality improvements in • phosphate, potash and lime across the field by matching product application rates to soil variability, nutrient levels, pH, nutrient off-take and crop requirements. Electromagnetic inductions (EMI) cereals and potatoes. The ability to scanning to assess soil variability return to precisely the same – EMI systems measure soil sampling point five or ten years later electrical conductivity which is greatly enhances the value of soil determined by soil properties. sampling to monitor trends in This technique alone is insufficient nutrient levels. to assess P and K variability but How can it help you? can add to conventional P and K Whole-farm trials in the Borders maps. Several companies offer have shown savings in lime • this as a commercial service. application of 50% and savings on Improved phosphate, potash and phosphate and potash of 27%. This lime utilisation resulting in improved gross margins • • Where yield maps are available Reduced variability in yield and use them to calculate variable quality, e.g. common scab in phosphate and potash off take. How can it help the environment? • • determine an application strategy based on the in-field variability. Apply using variable rate technology including where necessary Global the soil above the levels needed Positioning Systems (GPS) – several for optimum production GPS and rate control systems are water pollution from phosphate run off and leaching Availability and use now available commercially. Several commercial companies in Scotland now offer a complete targeted application service from assessing variability, map production Assess in-field phosphate, potash through to variable application and and pH variability using techniques subsequent monitoring. This type of such as: technology can also be used for variable application of other inputs, • Soil sampling – this should be e.g. sulphur, copper and done every 4 to 5 years, but magnesium. more often where phosphate, 240ha dairy and potato farm, after machinery purchase have been Use all the information available to Reduced build up of nutrients in Reduced groundwater and surface £20,000 over a five year period on a all costs of sampling analysis and potatoes caused by acid patches in fields has led to net savings of over taken into account. (Source: CSC CropCare) 27 9 Crop Nutrition section 2 Crop Nutrition Targeted Phosphate, Potash and Lime Application Further information Electromagnetic induction (EMI) scanning systems used to assess soil variability ADAS, Boxworth How much will it cost you? Capital cost 28 Operating cost Cost benefits EMI scanning instrument ££ Variable rate control systems ££ Use of contractors to assess soil variability using EMI £ Soil sampling £ Savings can be made by the variable application of phosphate, potash and lime Technical tip • • • FACTS qualified advisers • The Wheat Growth Guide, 1998. HGCA • P and K fertiliser planning, using soil and plant analysis to plan fertiliser use, 2000. HGCA • Precision farming of cereals, practical guidelines and crop nutrition, 2002. HGCA • • • • SAC Technical fertiliser notes remember to take into account any responsive crops to be included in the rotation (e.g. potatoes and vegetables) and make allowances for any animal manure that has been or will be applied. AICC The Precision Farming Alliance Electronic Communication • Improved Fertiliser Spreading Characteristics • Improved Targeting of Fertiliser Close to Field Boundaries • • • Boom Fertiliser Spreaders the field. However, when potash applications AIC • • • maintenance levels across planning phosphate and Fertiliser Recommendations for Agricultural and Horticultural Crops (RB 209). MAFF Technology links Always aim to keep phosphate and potash at Precision farming advisers Fertiliser Planning Targeted Nitrogen Application Manure-Value Diagnostics Yield Mapping 10 Crop Nutrition section 2 Crop Nutrition Improved Fertiliser Spreading Characteristics What is it? • The ability to spread fertilisers How can it help the environment? uniformly with any type of spreader • • Reduced groundwater and surface Ground conditions at the time of spreading The type and quality of the fertiliser depends on the physical properties water pollution as improved of the material. Flow characteristics uniformity of application With any product, it is important to through a metering system are minimises potential leaching set up and calibrate the spreader for important for all types of spreaders. losses both application rate and pattern. For spinning disc and spout • machines, the size distribution of the Reduced contamination of field margins and hedgerows particles is critical particularly when operating at bout widths greater important, many growers do not Availability and use than 18m. Good spreading characteristics for a fertiliser are affected by the way in which it is made, packaged, stored and handled on the farm. Many materials are hygroscopic and will absorb moisture if exposed to the atmosphere leading to caking and poor spreading performance. Good quality fertilisers should be widely available. For straight nitrogen products the ‘SP’ quality mark indicates good spreading quality and a consistent supply. This scheme is operated on behalf of the Agricultural Industries Confederation in the UK and is audited by Lloyds. It is to be extended to other How can it help you? materials. • Improved uniformity of spreading Where quality is not known, ask for particularly at wide bout widths: information about less lodging risk and better • utilisation leading to improved high percentage of particles less Improved timeliness and labour utilisation, and reduced crop losses due to the ability to than 1mm in diameter. • • Particle strength – it should not be possible to break particles operate with wide bout widths • Particle size distribution – a sieve box test will show if there is a yields and quality • Whilst all of these factors are easily with your fingernails, nor Improved fertiliser handling – less should the fertiliser be excessively break-up of material and less dust dusty. Consistent quality means less need for frequent re-calibration of A number of factors affect the spreader accurate spreading of fertiliser: • • The condition of the spreader The set-up and calibration of the spreader • The skill, experience and training of the operator • Weather conditions at the time of spreading fully appreciate the effect of changes in prill quality on crop yields and hence on profitability. The spread pattern rating system (SP) has been developed to test the various nitrogen fertilisers on the market, and provide a quality standard. The fertiliser is tested independently by Silsoe Research Institute. The SP system measures the two most significant factors in spreadability: throw and flow. The flow is the movement through the hopper and into the spreader vanes or boom, and the throw is the spread across the working width. 29 10 Crop Nutrition section 2 Crop Nutrition Improved Fertiliser Spreading Characteristics An operating rig used to test fertiliser spreading qualities Technical tip Granular and prilled fertilisers from different sources have differing flow rates and spreading characteristics. The spreader must be set-up and calibrated to take account of these factors according to the manufacturers’ recommendations Further information Silsoe Research Institute 30 As different granules behave differently in different machines, it is critical to • • • • • • FACTS qualified advisers Fertiliser suppliers Spreader manufacturers AIC AICC SRI tray test the spread of the machine (disc or pneumatic) with all the Technology links fertilisers used on the farm. A coefficient of variation (CoV – a measure of • Targeted Nitrogen Application • Targeted Phosphate, Potash and Lime Application • Improved Targeting of Fertiliser Close to Field Boundaries • Boom Fertiliser Spreaders the variation of spread across the working width) of less than 10% should be the aim. The striping of a cereal crop by poor application does not become apparent until the variability exceeds 20%. Thus a great deal of wasted fertiliser and lost yield can occur before striping is visible. Work at the Silsoe Research Institute has calculated the direct effects of poor spread pattern on yield and financial return. Poor spreading can result in a £6-12/ha margin reduction, which at 160kg N/ha equates to £13-26/ha of fertiliser for a 34% N product. The financial impacts may be even greater where quality specifications are important for crops such as malting barley and winter wheat. How much will it cost you? Capital cost No capital costs involved - Operating cost Some increase in material costs £ Cost benefits Increased cost of material should be readily off-set 11 Crop Nutrition section 2 Crop Nutrition Improved Targeting of Fertiliser Close to Field Boundaries What is it? Improved targeting of fertiliser close Availability and use • Use of specialised spout (spout machines only) • to field boundaries reduces Most fertiliser spreader contamination of hedgerows and manufacturers will offer a spread pattern for each disc on a watercourses. High levels of fertiliser mechanism for modifying the twin disc machine applied into the base of hedgerows distribution pattern from a spreader and field margins have been shown close to the field boundary although Boundary limiting systems for to disturb the balance of flora in for any particular machine there will fertiliser spreaders are a well- such areas so as to limit probably not be a choice of system established technology that has been biodiversity. Most single point to be used. exploited commercially in a number Use of different feed rate and disc of ways. The use of such systems fertiliser spreaders (e.g. disc or spout machines but not boom A number of approaches have been avoids a ‘tailing off’ of application spreaders) rely on matching developed for changing the spread rate close to the field boundary overlapping spread patterns. This pattern from such machines to limit although the uniformity of means that at the field boundary fertiliser loss into the boundary application in the last field bout is substantial amounts of fertiliser may including: likely to be less than that obtained with fully over-lapping patterns. be spread beyond the edge of the field giving a direct contamination • disc (disc machines only) risk to water as well as indirect effects on biodiversity. The use of a specialised border • 31 Tilting the whole spreading machine How can it help you? • Reduced loss of fertiliser from the • Changing the position of the feed to the disc productive area of the field • Improved spreading uniformity up Changing the distribution pattern by tilting the whole machine to the edge of the field • Improved management of field margins • Helps with adherence to quality assurance protocols • Reduced weed growth in field boundaries How can it help the environment? • Reduced risk of watercourse contamination Improved biodiversity in field margins and hedgerows Silsoe Research Institute • 11 Crop Nutrition section 2 Crop Nutrition Improved Targeting of Fertiliser Close to Field Boundaries A distribution pattern obtained from a disc spreader. Boundary control devices will modify one side of this pattern Technical tip Although operation of 280 boundary limiting systems is Silsoe Research Institute C/L Fertiliser rate as % of mean rate 240 200 160 120 necessary to undertake separate calibrations for such systems. It is also important to remember that most boundary limiting systems only operate on one side of 80 the machine. Hence it is 40 important to carefully plan spreading in each field so 0 0 5 10 15 20 25 30 35 40 that you drive round the outside in the right direction Pattern width, m The use of boundary limiting systems to reduce the fertiliser spread into the 32 straightforward, it may be field boundary is a requirement of some crop assurance scheme protocols Further information (e.g. Scottish Quality Cereals) and is likely to be a component in Nitrate • Crop Assurance Scheme action plans • • • • • FACTS qualified advisers Vulnerable Zones (NVZ) action plans. Note: Boom spreaders can achieve control of fertiliser application into the field boundary with no modification. How much will it cost you? Capital cost Spreader components for machines that, for example, change discs Operating cost Cost benefits • Targeted Nitrogen Application £ • Targeted Phosphate, Potash and Lime Application - • Improved Fertiliser Spreading Characteristics • Boom Fertiliser Spreaders Capital and operating inputs needed to deliver benefits AICC - No additional materials – may be a small saving in fertiliser use AIC Technology links Some cost due to time and expertise needed to set up the boundary limiting systems AEA £ Machines that change settings or adjust the mounting angle will involve no additional cost Spreader manufacturers 12 Crop Nutrition section 2 Crop Nutrition Boom Fertiliser Spreaders What are they? Availability and use Boom spreaders use nozzles on a Boom fertiliser spreaders take two boom to deliver either liquid or solid forms, namely: depend on the pump capacity. Contractors can be employed to reduce capital costs. fertiliser materials. Solid materials A crop sprayer equipped to apply Pneumatic fertiliser spreaders are air flow. Such application systems liquid fertilisers, often using less readily available and relatively are capable of achieving high levels relatively large diameter boom expensive to purchase and maintain of uniformity, provided the boom is supply lines to handle large flow when compared with disc type well mounted via a suspension rates and fitted with specialist spreaders. Booms tend to be heavier system that minimises the nozzles; or than those on crop sprayers and this are conveyed to the nozzle using an transmission of vehicle roll and yaw • • Pneumatic spreaders in which to the boom. Boom widths typically rigid plastic pipes secured to a match those of the sprayer to enable boom are used to supply the use of tramlines for a number of fertilisers in a high speed air operations; 18 and 24m are stream to deflector plate nozzles common widths. Separate sections spaced along the boom. • • • speed; air flow to all delivery pipes Methods of adapting crop sprayers is balanced as is the performance of to apply liquid fertilisers are widely the metering segments so that a available. Some machines will use uniform distribution pattern can be dual lines such that the larger achieved. diameter pipes can be used for fertiliser application and smaller application pipes with reduced residual volumes Liquid fertiliser delivery with the can be used for pesticides. Fertiliser sprayer can reduce investment in nozzles and dribble bars apply machinery streams of liquid and aim to Effective spreading can be done in minimise crop scorch by limiting the a wider range of weather contact between applied material conditions and crop leaves. Fertiliser nozzles The distribution pattern from pneumatic spreaders or liquid application with a crop sprayer is of a different form to that of disc or and dribble bars are widely available • similar metering system driven from rate is independent of forward Improved uniformity of fertiliser How can they help the environment? using a segmented fluted roller or a ground wheel so that application off to allow less overlap on How can they help you? to a maximum of 24m. Fertiliser is metered into the delivery tubes of the boom can be switched on and headlands and butts. has tended to limit working widths from specialist manufacturers. Using spout type machines – it is even across the width – so that accurate bout matching is very important. This makes such application methods suited to tramline operation. such machines to apply fertiliser is straightforward, but work rates Reduced groundwater and surface water pollution as improved uniformity of application • Fewer losses at field boundaries reducing contamination of hedgerows and field margins Silsoe Research Institute losses Dribble bar Hardi International A/S minimises potential leaching Stream nozzle 33 12 Crop Nutrition section 2 Crop Nutrition Boom Fertiliser Spreaders Pneumatic fertiliser spreader in operation Technical tip Many automated systems for patch spraying can also be used to provide targeted application of liquid fertilisers. Further information Silsoe Research Institute How much will it cost you? 34 Capital cost Operating cost • • • AEA Targeted Nitrogen Application • Targeted Phosphate, Potash and Lime Application £ • Improved Fertiliser Spreading Characteristics - • Improved Targeting of Fertilisers Close to Field Boundaries Pneumatic spreaders: no operating costs Cost benefits Sprayers: benefits can be obtained at a low cost Pneumatic spreaders: costs are higher and results can be achieved by other methods AICC • ££ through higher maintenance and where a other than standard maintenance AIC Nitrogen Diagnostic Technology Sprayers: a slight increase in operating costs storage tank is required (hire charge) Nozzle, sprayer and spreader manufacturers • £ Pneumatic spreaders: pneumatic machines represent a high cost investment FACTS qualified adviser Technology links Sprayers: capital cost is low (purchase of nozzles) particularly if sprayer is fitted with dual lines • • - 13 Crop Nutrition section 2 Crop Nutrition Manure-Value Diagnostics What are they? Availability and use Agricultural manures (solid manure The nutrients available to the crop, and slurry) contain useful amounts particularly nitrogen, will depend on of plant nutrients. However, their the manure or slurry type, the soil variable nature means that their type, the timing of application and nutrient content is often difficult to the application technique used. They predict. Manure-value diagnostics can be estimated using standard are techniques aimed at improving figures (e.g. tabulated figures) or the estimation of the manure computer software programs (e.g. nutrient content, allowing improved MANNER or EMA). ammonium nitrogen estimation. Prototype in-line nutrient sensors fertiliser planning. Both the manure’s that can estimate the nutrient value of slurry in real time have been developed, but such systems are not currently commercially available. Manure is a valuable resource that can bring considerable savings of inorganic fertiliser. For example, the excreta produced annually by a There are 3 main techniques typical dairy cow can provide currently available to help estimate nutrients worth £16.40 and pig the nutrient value of manure: manure applied at 35t/ha can supply standard values, sampling and nutrients worth £85/ha (see table). How can they help you? laboratory analysis and rapid on For some arable crops, organic farm methods such as hydrometers manures can supply all the for phosphate estimation and phosphate and potash the crop • Improved fertiliser planning hypochlorite oxidation methods (e.g. requires. Manures also supply useful resulting in savings on inorganic Agros or Quantofix meter) for quantities of sulphur and total nutrient content and its availability to the crop must be considered. • Help to comply with rules in Nitrate Vulnerable Zones (NVZs) • requirement for phosphate and potash How can they help the environment? • Reduced groundwater and surface water pollution from nitrate leaching and phosphate run off • Fertiliser value of organic manures Nitrogen In some situations, organic manures can supply the total Utilisation of manures as a resource rather than disposal of a waste product Caution: Livestock manures, especially pig and poultry manures, can contain heavy metals, particularly zinc and 35 magnesium. fertiliser Phosphate Potash Nutrients (kg) supplied by 100 dairy cows per year, assuming they are housed for 6 months 4800 1900 4800 % available to next crop following spring application 35 50 90 Fertiliser available per year (kg) to following crop 1680 950 4320 Value of manure fertiliser assuming nitrogen = 30p/kg; phosphate = 30p/kg; potash = 20p/kg £500 £280 £860 Typical nutrient content of 25% dry matter pig farmyard manure (kg/t) 7.0 7.0 5.0 % available to next crop following winter application 10 60 90 Fertiliser available (kg) to following crop assuming an application rate of 35t/ha 25 150 160 Value of manure fertiliser (£/ha) assuming nitrogen = 30p/kg; phosphate = 30p/kg; potash = 20p/kg £8 £45 £32 copper, which over the long term, e.g. more than 100 years, may result in toxic levels of these in the soil. MAFF RB 209 © Crown copyright material is reproduced with the permission of the Controller of HMSO and Queen's Printer for Scotland 13 Crop Nutrition section 2 Crop Nutrition Manure-Value Diagnostics Further information How much will it cost you? Capital cost Computer programs and standard values £ Rapid on farm methods £ Operating cost Analysis of samples by a laboratory £ Cost benefits Although there can be a cost associated with improved estimation of manure nutrient content, considerable savings on inorganic fertiliser can be made • • FACTS qualified advisers • Fertiliser Recommendations for Agricultural and Horticultural Crops (RB 209). MAFF • Managing Livestock Manures: Booklet 1 – Making better use of livestock manures on arable land; Booklet 2 – Making better use of livestock manures on grassland and; Booklet 3 – Spreading systems for slurries and solid manures. ADAS • PEPFAA code, Dos and Don’ts guide. Scottish Executive • • SAC Technical fertiliser notes • • AIC Technical tip Careful sampling is required to ensure the manure being analysed is representative of the stored material. This will require taking multiple 36 samples from a range of positions within the store or heap, mixing them together and then taking a sub-sample for analysis. Poor sampling will result in inaccurate manure-value estimation. EMA software. University of Hertfordshire The 4 Point Plan. Straightforward guidance for livestock farmers and contractors to minimise pollution and benefit your business. SEERAD, SEPA, SAC, NFUS, SNH, WWF, FWAG and BOC AICC Technology links • • • Electronic Communication • Targeted Phosphate, Potash and Lime Application • • Improved Manure Storage Fertiliser Planning Nitrogen Diagnostic Technology Improved Manure Application 14 Crop Nutrition section 2 Crop Nutrition Improved Manure Storage What is it? Agricultural manures (solid manure and slurry) are invariably stored on farms before they are spread. Poor storage can result in harm to the environment. Improved storage techniques can minimise the amount of nitrogen lost through ammonia volatilisation and increase the manure’s nutrient value to the crop. These techniques can also help with compliance in Nitrate Vulnerable Zones (NVZs). How can it help you? • Improved utilisation of manures to determine the storage capacity store, which is equivalent to 50 you require. A minimum storage tanker loads (Scotford and Williams, capacity of 4 months is 2001). recommended, but increasing capacity increases the flexibility Other studies have indicated that allowing manure to be spread when preventing rainwater from yards and the crops require the nutrients. In roofs entering slurry stores can some circumstances, it may be reduce the volume of slurry to be necessary to build a new store. spread by more than 600 tonnes per Failure to apply manure at a time year equivalent to 100 tanker loads when the crop requires the nutrients (Scottish Agricultural Pollution will result in environmental pollution Group, 2000). through ammonia volatilisation and nitrate leaching (see table). Relationship between time of application of manures and amount of available N remaining for spring growth resulting in savings on inorganic fertilisers • Helps comply with rules in Nitrate Vulnerable Zones (NVZs) • Available nitrogen effective for spring growth, % Autumn 0 – 20 Early winter 30 – 50 Late winter 60 – 90 Spring 90 – 100 Easier manure management and increased flexibility in timing of applications How can it help the environment? • Time of application Scottish Agricultural Pollution Group, Pollution Review, No. 14, August 2001 Reduced atmospheric pollution Sufficient storage for slurry may be from poorly timed manure achieved by reducing the amount of Consider using manure treatment application clean water entering the storage processes such as composting for system, e.g. rainwater runoff from solid manures, aeration, weeping roofs and yards. New covering wall, low rate irrigation systems and techniques can reduce both the separation for slurries. These rainwater entering the store, odour technologies can ease handling and emissions and the amount of increase the availability of the nitrogen lost through ammonia nutrients. Anaerobic digestion, volatilisation (by over 80%), thus either on farm or centralised can be resulting in more nitrogen being used to produce bio-gas. Centralised available to the crop. The lagoon digesters are now common in It is important to have sufficient pictured on the next page covers an Denmark, Germany and Sweden; storage to allow manure to be area of 525m2; assuming an the first one has been constructed in spread at the optimum time for crop average annual rainfall of 600mm, the UK and these units may provide uptake (usually in the spring). Use the cover would prevent 300 tonnes an alternative outlet for farm waste techniques such as standard values of water per year from entering the in the near future. • Reduced groundwater and surface water pollution from nitrate leaching and phosphate run off • Utilisation of manures as a resource rather than disposal of a waste product Availability and use 37 14 Crop Nutrition section 2 Crop Nutrition Improved Manure Storage Cover being fitted to a slurry store Technical tip Improved manure storage must form part of an integrated approach to manure management. The key requirements are: • Determine the nutrient content of the manure Silsoe Research Institute • Apply manures at the correct time (usually in the spring) • Apply evenly at the correct rate using techniques that minimise ammonia losses Further information • • FACTS qualified advisers • Fertiliser Recommendations for Agricultural and Horticultural Crops (RB 209). MAFF ££ • Guidelines for farmers in NVZs. Scottish Executive increase maintenance costs £ • Manure treatment processes ££ PEPFAA code, Dos and Don’ts guide. Scottish Executive • • SAC Technical fertiliser notes • • AIC How much will it cost you? 38 Capital cost Major capital investment required for new manure storage system ££ Major capital investment required for covering manure storage system ££ Treatment plants are likely to involve major capital investment Operating cost Cost benefits Covering storage systems is likely to Improved utilisation of manure reduces the use of inorganic fertilisers Note: Grants may be available for improving slurry stores in NVZs References EMA software. University of Hertfordshire The 4 Point Plan. Straightforward guidance for livestock farmers and contractors to minimise pollution and benefit your business. SEERAD, SEPA, SAC, NFUS, SNH, WWF, FWAG and BOC AICC Scotford I.M and Williams A.G. (2001). Practicalities, costs and effectiveness of a floating plastic cover to reduce ammonia emissions from a pig slurry lagoon. Journal of Agricultural Engineering Research 80 (3), 273-281. Scottish Agricultural Pollution Group (2000). Pollution Review No. 13. Technology links • • Manure-Value Diagnostics Improved Manure Application 15 Crop Nutrition section 2 Crop Nutrition Improved Manure Application What is it? Availability and use Agricultural manures (solid manure A reduction in ammonia emissions and slurry) are commonly spread can be achieved by rapid using broadcast spreaders which incorporation of solid manure and often have poor accuracy of slurries which are broadcast to bare application and can result in land. Care must be taken to avoid potentially damaging gaseous compaction or damage to soil emissions. Improved manure structure: incorporation should not application techniques are able to take place when soil conditions are achieve accurate application rates poor. Alternatively, for slurries, use (e.g. t/ha or m3/ha) and improved low level application systems such as lateral distribution whilst using band spreaders, trailing shoe techniques that minimise ammonia spreaders or injectors all of which losses. These techniques will help are commercially available. Often with compliance in Nitrate these types of machines are fitted Vulnerable Zones (NVZs) and quality with flow meters and control systems that accurately manage the application rate. In a novel system called Direct Ground Injection, slurry is injected into the ground without the need for soil engaging tines. These machines are not generally available in the UK but are now being used in Scandinavian countries. The figure shows that the use of low level techniques such as deep injection can result in ammonia volatilisation being reduced by up to 90% compared with broadcast spreading. assurance (QA) schemes. How can it help you? • Improved utilisation of manures resulting in savings on inorganic Comparison of slurry emissions from slurry spreading with and without the use of abatement techniques • Helps comply with rules in Nitrate Vulnerable Zones (NVZs) How can it help the environment? • Reduced atmospheric pollution from poorly applied manure • Reduced groundwater and surface water pollution from nitrate leaching and phosphate run off • Utilisation of manures as a resource rather than disposal of a waste product Caution: In certain conditions, such as light gravelly soils, injection of slurry – especially deep injection – can result in increased nitrate leaching and watercourse pollution. Steeply sloping ground or stony soils may not be suitable for slurry injection. % ammonia emission compared with broadcast spreading fertilisers 100 75 50 25 0 Broadcast spreading Rapid incorporation (within 6 hours) Band spreading Shallow injection (7cm) Deep injection (25 cm) Defra, Ammonia in the UK © Crown copyright material is reproduced with the permission of the Controller of HMSO and Queen's Printer for Scotland 39 15 Crop Nutrition section 2 Crop Nutrition Improved Manure Application Caution: Do not over apply manures, especially in NVZ, where the Technical tip limit is 250kg/ha organic nitrogen for grassland and 210kg/ha organic nitrogen for arable (reducing to 170kg/ha organic nitrogen after four The manure’s physical years). characteristics (e.g. dry matter content, straw Typical manure application rates to achieve 250 and 170 kg/ha content, fresh or old) will organic nitrogen affect spreader performance. It is important that the Manure type Application rate to achieve 250kg/ha N 170kg/ha N 36t/ha 24t/ha 8t/ha 3t/ha 83m3/ha 57m3/ha spreader is calibrated based on the type of manure used to ensure the required Pig manure 25%DM Broiler litter 60% Dairy slurry 6% amount is applied. Further information MAFF RB 209 © Crown copyright material is reproduced with the permission of the Controller of HMSO and Queen's Printer for Scotland • • FACTS qualified advisers • Fertiliser Recommendations for Agricultural and Horticultural Crops (RB 209). MAFF • Guidelines for farmers in NVZs. Scottish Executive • PEPFAA code, Dos and Don’ts guide. Scottish Executive • • • • SAC Technical fertiliser notes Some solid manure spreaders cannot achieve low application rates (less than 40 10t/ha), which results in over application of manures with high concentrations of nutrients, such as poultry. How much will it cost you? Capital cost Replacing manure spreading equipment is a major capital investment ££ Hanging low level application systems on the Operating cost Cost benefits back of an existing tanker is a cheaper option £ Rapid incorporation of manure £ Low level application systems £ EMA software. University of Hertfordshire AEA AIC AICC Costs offset by more efficient use of nutrients contained in agricultural manures and savings on inorganic fertiliser Note: As an alternative to buying new equipment, consider using a contractor’s spreading services Technology links • • Manure-Value Diagnostics Improved Manure Storage 16 Crop Nutrition section 2 Crop Nutrition Precision Irrigation What is it? • Irrigating at night reduces water evaporation rates This is making better use of your supply to the specific needs of the There are also several techniques crop. Improved use of irrigation that can be used to improve water water can be achieved using various management on farms. This is techniques such as improving the normally achieved by measuring distribution of the water or water available to the crop in the measuring and/or predicting water soil via sensors (probes) and/or demand by individual crops. using weather data to derive evapotranspiration rates. • Improved water use and better crop performance • • • Technologies to achieve this include: • Mathematical models - water is used at a rate determined by the Improved crop quality by timely size of the crop canopy. applications However, certain crops have Inform legislators and the general limitations in their ability to take public that water for irrigation is up water. Models take this into being used responsibly account in order to measure Help comply with new regulation water use by a crop. on water use How can it help the environment? More efficient use of water resources distribution pattern resulting in improved water usage. • Trickle irrigation for some crops can greatly reduce water consumption achieve as accurate measurement of water use as possible. This information can then be used to estimate water use in nearby fields. It should be noted that all measuring techniques measure soil water in the vicinity very accurately when set up correctly but they only measure water use between two points in time rather than measure directly what the plant has used. Note: The uniformity of water being under-irrigated, reducing yield prediction of evapotranspiration and crop quality. Other parts of the rates. A large network of remote field are over-irrigated, wasting in-field weather stations is water and leaching out fertiliser. • Measuring techniques – example neutron probes or they have a much better field so that they are replicated to This results in parts of the field amount of water in the soil, for boom) instead of rain guns as concentrate measurements in one conditions to improve the water, including: (e.g. centre pivot or transverse information. It is often best to especially poor in windy conditions. techniques that measure the • when to irrigate based on very little used to monitor environmental improve the application accuracy of Using boom irrigation systems growers may make judgements on Weather stations – they can be available in Scotland. Availability and use Several techniques can be used to more than two sites per field. Hence, distribution from rain guns is • • techniques in fields are point specific and instrument cost often precludes irrigation water to match the water How can it help you? All assessments using measuring EnviroScan diviners. 41 16 Crop Nutrition section 2 Crop Nutrition Precision Irrigation How much will it cost you? Capital cost Boom irrigation system Technical tip ££ When choosing irrigation systems, ensure that the Specialist equipment for monitoring soil moisture is normally hired Operating cost - correct pump and pipe size combination is used. Using Operating boom irrigation systems can too small a pipe will increase reduce operating costs compared with rain guns higher operating costs. Fully Contractor charge for hire and installation maintain any system: worn of the probes, regular reading and pumps and leaking pipes not interpretation Cost benefits the pressure resulting in £ only waste water but also increase the operating costs. Improved margins will be achieved through improved yields and quality Further information 42 • • BPC Technical Information • • • • • • • • • CSC PotatoCare Irrigation equipment suppliers CUPGRA SAC SEERAD SEPA SCRI AEA AIC AICC Technology links • Internet Information, Prediction Schemes and Tools • Decision Support Systems 17 Crop Protection section 2 Crop Protection Crop Diagnostics What are they? Crop diagnostics are products which allow fungal and viral disease, and nutrient deficiency to be diagnosed. Correct identification helps to improve the targeting of inputs. This bags for sending in samples and previously possible, enabling the results can be back within the week. industry to adopt early anti- Tests are available for disease resistance strategies. presence or identification, presence of fungicide resistance, presence and Delays arising from laboratory tests species of potato cyst nematode and can limit the usefulness of the plant nutrient status. approach, which has a wider usually involves the sending of samples to specialist laboratories for diagnosis although some in-field kits are now available. adoption as an aid to plant nutrition For example, a test based on the than for diagnosis of plant disease. malate:sulphate ratio now allows sulphur deficiency in oilseed rape Some in-field diagnostic kits are How can they help you? and cereal crops to be predicted with available and others are being more confidence. It also allows the developed for identification of crop success of the corrective treatment diseases e.g. potato blight and plant • Improved diagnosis of crop to be monitored. It is now being viruses. disorder, avoiding unnecessary developed for other crops. In-field diagnosis kits are widely expenditure • • Improved choice of product, level Biotechnology-based techniques used by inspectors of Scottish seed of input or choice of technique to such as Polymerase Chain Reaction potato crops for the diagnosis of tackle problems (PCR) are being used to identify viruses. The test device is packaged seed stocks of cereals that do not together with a system that is used require seed dressings for the to extract sap from the plant control of seedling diseases. These material (Bottle and Ball extraction techniques also allow the detection method). A few drops of the sample of the development of fungicide will then be placed on the device as resistance at an earlier stage than shown in the diagram. Identify deficiencies, disease or fungicide resistance before they result in yield and quality reduction but still in time to correct by the appropriate use of inputs • • Reduced doses and costs In-field test devices Help to justify treatment programmes to quality assurance auditors, buyers and processors How can they help the environment? • Reduced amount of pesticides and nutrients in the environment Availability and use based and require specialist knowledge for interpretation. Sampling kits are often readily available from specialist laboratories. They usually include postage-paid CSL, Crown Copyright Most of the tests are laboratory- 43 17 Crop Protection section 2 Crop Protection Crop Diagnostics Technical tip The biggest likely error source is at sampling. It is essential that the sample is representative. Representative sampling requires a very structured approach to deciding where to collect samples from in order to help ensure useful results from the test. Further information CSL, Crown Copyright 44 How much will it cost you? Capital cost No capital investment required Operating cost Small additional operating costs compared with standard practice Cost benefits £ • • • • • • • • • AIC AICC BPC CSL Pocket Diagnostics CSC PotatoCare HGCA PGRO SAC SCRI Matching crop inputs more closely with crop requirements will improve margins Technology links • Internet Information, Prediction Schemes and Tools • • • • Variety Choice Novel Seed Treatments Decision Support Systems Appropriate Fungicide Use 18 Crop Protection section 2 Crop Protection Monitoring Insect Pest Activity What is it? Availability and use Monitoring pests involves regular on- There are now systems where farm sampling in order to assess the manufacturers of key insecticides levels of insect pest activity. The monitor progress of the insect pest information collected will determine and supply the relevant information, the need to treat with an insecticide usually by electronic means. The and helps to identify the optimum extent and intensity of the laying of timing of treatment. The information wheat bulb fly eggs (to indicate the is provided regularly to those necessity for seed dressings) as well requesting the service (e.g. as the progression of egg hatch (to monitoring of wheat bulb fly hatch) optimise spray timing) are good or by direct measurements on the examples. Action threshold levels are generally available (e.g. 66% tillers infested for late aphid treatments in winter wheat, 10 or more pea moths in either of the two traps on two consecutive occasions in combining peas for seed and human consumption). farm concerned (e.g. in-field threshold techniques for In-field assessments can be made leatherjackets). either by field observation (e.g. aphid numbers in crops), by using How can it help you? • Improved risk analysis and decision making • farm built traps (e.g. slug traps) or by purchasing traps (e.g. pheromone traps for pea moth, sticky traps for monitoring carrot root fly and pollen Reduced costs by avoiding beetle). unnecessary applications of insecticides • • The on-farm information may be Improved timing of application supplemented by information from and hence utilisation of key representative sites (e.g. aphid insecticides suction traps at SCRI). All purchased Helps with adherence to quality traps, where appropriate, are assurance protocols modestly priced for the information they provide. Learning requirements How can it help the environment? • in some circumstances specialist advice may be necessary to interpret non-target species and beneficial results. Reduced amount of insecticides in the environment • are not normally required, although Reduced impact of insecticides on insects • are fairly minimal and contractors Increased food sources for birds and other wildlife 45 18 Crop Protection section 2 Crop Protection Monitoring Insect Pest Activity A typical Wheat Bulb Fly Report produced by Dow AgroSciences: WHEAT BULB FLY Following is egg hatch and plant invasion data for 18 February 2004. Egg hatch samples were only taken at the Yorkshire site this week. Site Date Sampled % Hatch % Plant Invasion % Larvae in Instar 1 2 3 Suffolk Ixworth Thorpe (mineral) 16/02/04 no sample 0 0 0 0 Stuntney (organic) 16/02/04 no sample 32 74 21 5 Holme (silt) 16/02/04 no sample 29 91 9 0 16/02/04 no sample 8 50 50 0 16/02/04 33.3 24 100 0 0 Cambridgeshire Lincolnshire Morton (silt) Yorkshire 46 High Mowthorpe (mineral) Below is the Pestwatch issued on Friday 20 February 2004. Report 6 Wheat Bulb Fly 20/02/04 Larval plant invasion has advanced steadily over the past week, with more second instar larvae starting to appear. We are now at the optimum timing for deadheart sprays in all southern and eastern risk areas. Now is the last opportunity to get maximum effect from an egg hatch application of Dursban* WG at all risk sites in the north of England and Scotland. % Plant Invasion 18 Feb 2004 100 90 80 70 60 50 40 30 20 10 0 Suffolk Mineral Cambs Organic % Plant Invasion Cambs Silt % 1st instar Lincs Silt % 2nd instar Yorks Mineral % 3rd instar Action: Use Risk Assessment Charts to identify fields at high risk. These are late drilled, e.g. following sugar beet, or backward crops with few tillers and poor overall establishment. Application of Dursban WG at 1.0kg/ha should be made as soon as possible to all crops in the north of England and Scotland considered to be at risk. If necessary, Dursban WG can be applied to frosty ground but should NOT be tank mixed. Applications of dimethoate should now be considered at all other risk sites. Always read the label. Use pesticides safely * Trademark of Dow AgroSciences LLC Dursban WG contains chlorpyrifos Dow AgroSciences 18 Crop Protection section 2 Crop Protection Monitoring Insect Pest Activity How much will it cost you? Capital cost Small capital investment required for traps Operating cost No additional cost where crops are already being regularly monitored. Cost benefits Savings compared with standard practice Technical tip £ Make sure that sample sites are representative and - regularly monitored. Where it is identified that insecticides are necessary, use ones that take account of beneficial insects such as carabid beetles, ladybirds and hoverflies. This reduces costs, avoids resistance developing and keeps disruption of beneficial species to a minimum. Further information • • • • • • • AIC AICC HGCA PGRO Rothamsted Research SASA SCRI Technology links • Internet Information, Prediction Schemes and Tools • • • • • Variety Choice Novel Seed Treatments Decision Support Systems Co-ordinated Slug Control Appropriate Insecticide Use 47 section 2 48 19 Crop Protection section 2 Crop Protection Decision Support Systems What are they? Availability and use Decision support systems (DSS) are There are many decision support computer based programs that help systems currently available. The list with decision making on a field-by- below provides a few examples but field basis. They use inputs such as there are many others available or weather, soil and crop data to becoming available. • service to track confirmed and potential blight outbreaks in your area. • HGCA provides a light leaf spot forecasting service for oilseed rape based on a model developed support decisions on pesticide use. Similar computer programs for BPC provides a blight mapping • at Rothamsted. ArableDS is an integrated suite of • recommending fertiliser inputs are decision support systems to assist described within the TIBRE Arable the farmer and adviser. Wheat Management for Agriculture aims Handbook in the data sheet Disease Manager (WDM) is the to help farmers improve the ‘Fertiliser planning’. first of the series to be made environment by using the available. It can help farmers principles of environmental make decisions about spray management systems. It timing, product choice and dose. contains a wide range of decision Other modules currently being support tools e.g. pesticide developed include disease and database, guide to LERAPs, soil pest management of oilseed rape, erosion risk assessment, a weed management support nematode risk assessment. How can they help you? • Improved risk analysis and decision making • Reduced costs by saving treatments or improved targeting • Improved timing and work planning • system and a simulation of nitrogen dynamics in arable land. • distributors and suppliers have DSSs – check which ones are Helps justify treatment Package for Potatoes, developed available for use. programmes to quality assurance by SCRI, combines real on-farm auditors, buyers and processors and commercial data with the How can they help the environment? a ‘virtual crop’, allowing you to test your management decisions and monitor the likely outcomes. Reduced amount of pesticides in In particular, it helps with the environment • Pesticide manufacturers, MAPP – Management Advisory best scientific knowledge to create • • EMA – Environmental planning of desiccation dates, Reduced groundwater and surface water pollution resulting from improved timing and targeting of inputs crop quality and seed rates. • CSC PotatoCare PLANT-Plus is a Scottish service based on over 20 in-field radio-linked weather stations connected to a potato blight prediction model first developed in The Netherlands. The system uses weather data to provide updates on blight risk. Decision support systems are often tailored to given climatic conditions so ensure that the program you are using is suitable for your situation. Always use the best data available, as poor data can result in poor recommendations. 49 19 Crop Protection section 2 Crop Protection Decision Support Systems Example of the Rothamsted Research light leaf spot forecasting Technical tip service (available at www3.res.bbsrc.ac.uk/leafspot/) Decision support systems are constantly being updated and new ones developed. Use the latest version of the DSS available to ensure the best 2002/03 recommendations. 70% + Further information • • • • • • • • 68% 50 45% 41% © 2004 Rothamsted Research Ltd 9% 53% For improved prediction you can input area, variety and date of sowing. The values represent the percentage of crops with greater than 25% affected plants. How much will it cost you? Small initial outlay may be required to purchase decision support systems £ Operating cost Unlikely to be any operating costs - Cost benefits Improved decision making can result in increased profitability AIC AICC BPC CSC CropCare HGCA SAC SCRI Technology links 26% 15% Capital cost ADAS • • Electronic Communication • • • • • • • • • Novel Seed Treatments Internet Information, Prediction Schemes and Tools Fertiliser Planning Precision Irrigation Crop Diagnostics Monitoring Pest Activity Co-ordinated Slug Control Appropriate Herbicide Use Appropriate Fungicide Use Appropriate Insecticide Use 20 Crop Protection section 2 Crop Protection Co-ordinated Slug Control What is it? from early/mid July through to However, cereal seed, when in a August and if harvest is delayed. smeared slot as a result of direct Co-ordinated slug control provides a decision framework to minimise the damage from slugs by integrating cultural control with the responsible use of molluscicides. Prevention of crop damage by cultural techniques is cheaper than control with pellets. Sowing date, depth of drilling of drilling, is at particular risk when The most significant factors influencing slug populations and crop the soil is too wet. • of winter cereals and oilseed rape information should be used to can better withstand slug attack develop a co-ordinated control as emergence and early growth strategy in order to minimise the use are faster and the crop is more of pellets. able to compensate for slug cereals, field history, and current soil and weather conditions all have a part to play. Slug pellets should be damage. • Crop Rotation. Slugs thrive under crops providing dense the last resort once baiting has How can it help you? • Reduced risks of crop failure from preceding crop. ‘Double low’ rape slug damage crops also have a higher risk of Better yields and easier crop slug damage. Carabid beetles, management resulting from which are slug predators, can optimum plant populations reduce slug numbers significantly but are affected by crop rotation and inappropriate insecticide use. reduced slug pellet use beetles is also important. • • • • Soil type. Heavier soils support higher slug populations. unconsolidated seedbeds increase Reduced impact on non-target the risk of slug damage by species resulting in improved allowing easier movement of the biodiversity pest through the soil. The approach requires the integration of both cultural and chemical methods. Slug pellets alone will not prevent damage. Cereals and oilseed rape are vulnerable from sowing to the tillering/four leaf stage. Susceptible varieties of potatoes are vulnerable damage before they emerge and sowing to a depth of 4 cm helps to minimise the damage. • Weather conditions. Cool moist conditions favour slugs’ growth and reproduction as it enables them to move more easily through the soil. • Slug bait traps should be used in high risk situations to indicate whether slugs are feeding on the soil surface and are hence vulnerable to Seedbed conditions. Cloddy, the environment Availability and use are most vulnerable to economic Provision of habitat for carabid How can it help the environment? Reduced amount of pesticides in highest risk from slugs. Cereals build-up of slug populations in the Lower costs resulting from Seed depth. Shallow sown or broadcast cereal crops are at particularly at risk following oilseed rape or peas due to the • • shade. Winter wheat is indicated there is a problem. • Sowing date. Earlier sown crops damage are given below. This pellets. Bait traps with methiocarb pellets should be used to enable accurate assessment. When the soil surface is moist and suitable for slug activity, a minimum of 10 small Cultivation. Higher slug numbers squares (at least 15cm x 15cm) of are associated with non-plough relatively impervious and well tillage but this does not insulated material (such as plywood necessarily mean that crops or roof tiles) should be placed over established using minimum tillage some slug pellets or layers mash in are at more risk. This may be the known danger areas. Treatment because there are more of the field may be worthwhile once alternative food sources for slugs slugs are detected in all or nearly all in min-tilled crops and that the traps. For wheat, the threshold seedbeds tend to be more trap catch is four slugs per trap over consolidated in such crops. a three-day period. 51 20 Crop Protection section 2 Crop Protection Co-ordinated Slug Control A rolled firm seedbed, unlikely to suffer from slug problems Technical tip 2 At least 40 pellets/m are required for effective coverage. Repeat ‘low dose’ approaches can be successful in cereals provided that sufficient pellet numbers are Silsoe Research Institute used to achieve adequate coverage. In very high risk situations in cereals, the optimum time to apply pellets is 3–5 days before sowing. Length of effective control period by the pellets will also depend on the durability of the formulation. 52 A cloddy seedbed on heavy land, likely to suffer from severe slug problems Further information Silsoe Research Institute • • • • • • • No capital investment required Operating cost Increased management time to develop • • • - and introduce strategy may be compensated for by easier crop management Cost benefits Improved slug control will result in improved margins AICC BPC HGCA SAC SCRI Rothamsted Research Technology links How much will it cost you? Capital cost AIC - Minimum Tillage Monitoring Pest Activity Decision Support Systems 21 Crop Protection section 2 Crop Protection Improved Formulation and Packaging What is it? Improved formulation and packaging of pesticides can ease handling, • Approaches to minimising packaging loading waste being adopted by the crop Reduced risk of groundwater and protection industry involve: surface water contamination reduce packaging disposal problems and reduce point source pollution. reduced spillage during sprayer • Reducing the amount of packaging components Availability and use - use of higher activity chemistry - increasing the concentration in Formulations as gels, tablets or dry Many pesticides are now formulated flowable granules, rather than liquids as granules, tablets or gels for or powders, can be handled safely reasons of handling safety. However, and can be loaded rapidly into the it is not possible to formulate all sprayer. These can be dispensed in active ingredients in this way. pre-measured packs and can be Similarly water soluble packaging is recovered more effectively if spilt. not appropriate for all formulations. Granules can be packed into bags Returnable keg-type containers are that are more easily disposed of suitable and available for products than plastic bottles. with relatively high usage rates and - use bulk/re-usable containers are generally more suited to larger - re-use secondary packaging Re-usable containers used for liquid formulations - use of water soluble film packaging - • operations. use of lightweight containers Re-using packaging materials components, e.g. pallets formulations eliminate the need for • Re-cycle packaging the rinsing and disposal of used Even with ‘conventional’ containers containers. Water soluble packaging and liquid formulations, important is also a means of reducing both environmental and operator safety container contents and disposal and rinsing problems features relate to: subsequent container rinsing - promote complete use of although the unit size of the pack then dictates the volume with which • the sprayer can be loaded. • - support education and training disposed of be effectively rinsed – e.g. no facilitate good container rinsing Reduced spillage and operator hollow handles; • • - consider that energy recovery in Using a standardised 63mm cap approved facilities is the most Easier and rapid filling of the so that connections to closed suitable and economic solution sprayer giving faster work rates transfer systems can be made if for the disposal/recovery of used appropriate. crop protection packaging where viable collection schemes are Most containers for liquid formulations comply with the Less packaging material for disposal • product labels programmes designed to How can it help the environment? • instruction on all appropriate this is influenced by both formulation and container design; include a rinsing and disposal Ensuring that the container can Less packaging waste to be contamination risk • - minimise ‘glugging’ and splashing: How can it help you? • Pouring in such a way as to Reduced amount of pesticides in the environment resulting from reduced contamination from residues in containers and requirements for easy rinsing, pouring into induction hoppers and connection to other systems. available 53 21 Crop Protection section 2 Crop Protection Improved Formulation and Packaging How much will it cost you? Capital cost No additional capital expenditure involved Operating cost There may be an increase in the cost of formulations but this will generally be small Cost benefits Benefits are easily obtained by the user at only a modest increase in the cost of chemicals - Technical tip Care is needed when using water soluble products and £ packaging as dissolving will be influenced by water temperature in the tank. Allow adequate time for the product to dissolve and use sufficient agitation to ensure that the tank is fully mixed. Further information 54 • • • • AIC • Voluntary Initiative web site AICC CPA guides. Chemical manufacturers’ literature. Technology links • Appropriate Active Ingredient Use • Pesticide Handling Systems 22 Crop Protection section 2 Crop Protection Appropriate Active Ingredient Use What is it? Availability and use Appropriate active ingredient use Recently introduced pesticides involves the selection of pesticides (herbicides, fungicides and and tailoring of rates whilst insecticides) can provide effective maintaining control of weeds, crop control at lower quantities of active diseases and crop pests. It requires ingredient per hectare and help a knowledge of pesticides, weather reduce the impact on the conditions and other factors affecting environment provided that their their use. environmental profile is Caution: Although these products are easier to handle due to the equivalent on a gram for gram How can it help you? • • Reduced pesticide use basis to one of the older products. These pesticides are often supplied in granular formulation, which has Easier handling since many newer pesticides are in granular form benefits in terms of easier product reduced quantities required per hectare, there is still a potential risk arising from product leakage or spillage and contamination of the sprayer. An example are the sulfonylurea herbicides where a very small residual amount left in the spray tank can cause damage if applied to susceptible crops. Spray tanks should be cleaned out following the methods prescribed by the pesticide manufacturer. handling and reduced storage requirement. Caution: Using lower rates than the manufacturers’ label All are readily available and can recommendation is always at the easily be incorporated into existing grower’s risk. spray programmes with no specific How can it help the environment? • Reduced amount of pesticides in the environment • May enable less frequent pesticide applications in some circumstances • training requirement. The environmental profile of pesticides can be obtained from the Environmental Information Sheets (EIS) produced as part of the work of the Voluntary Initiative. For example, new potato blight products offer improved environmental and Less waste and packaging to toxicological profiles as indicated by dispose of their Environmental Information Sheets. They contain much lower active ingredient rates than more conventional alternatives and allow less frequent spray applications leading to much lower total active ingredient applications. 55 22 Crop Protection section 2 Crop Protection Appropriate Active Ingredient Use How much will it cost you? Technical tip Capital cost No capital investment required - There are now alternatives to Operating cost Possible increase particularly with insecticides £ isoproturon, a herbicide that Cost benefits Improved margins may be achieved where control is more effective than with products that have a higher active ingredient rate/ha is commonly found at above prescribed limits in surface waters due partly due to its high dose of active ingredient. Further information 56 • • • • BASIS advisers • • • • • The UK Pesticide Guide PSD web site EMA Environmental Information Sheets AIC AICC CPA SAC Technology links • • Minimum Tillage • • • • • Appropriate Herbicide Use Improved Formulation and Packaging Appropriate Fungicide Use Appropriate Insecticide Use Pesticide Mixtures Pesticide Handling Systems 23 Crop Protection section 2 Crop Protection Appropriate Herbicide Use What is it? Appropriate herbicide use involves weeds (like creeping thistle) in the Availability and use spring. In general, residual the optimal use of herbicides. This is Treatment thresholds should be used at the appropriate rate required to pragmatically. Research has shown achieve adequate weed control to that thresholds are difficult to safeguard yield and crop quality, measure, because of variation in minimise harvest delays and avoid weed numbers within a field. In unnecessary long term weed build addition, there are limited up in the soil. This requires opportunities to apply thresholds knowledge of the efficacy of the because of the impact on weed herbicide (or herbicide mixture) on populations in future crops of seed individual weed species as well as shedding from untreated weeds. understanding the impact of weather The use of appropriate herbicide conditions, crop competition and rates to manage weeds has been weed size on herbicide efficacy. An proven to be the most profitable appreciation of crop competition and long term option. herbicides at reduced rates are most active when the seedbed has a fine, even, moist tilth and weeds are just emerging in good growing conditions. The sulfonylureas are an example of a foliar-acting herbicide group with robust recommended rates and wide weed spectra. This enables reduced rates to be used for broad-leaved weed control in cereals, if for example, conditions are favourable, the target weeds are very susceptible and, particularly, if they the relative competitiveness of weeds is also important. have a suitable partner herbicide in Timing of applications and spraying the tank mixture. Mixing herbicides conditions are more critical at How can it help you? • • with a different mode of action is not reduced rates than recommended always essential to efficacy, but is a label rates. Hence careful Reduced herbicide costs good anti-resistance strategy management is required. Many of particularly as some broad-leaved Helps to increase the number of the newer herbicides are very predators of insect pests because effective on certain weed species of the survival of less competitive and good knowledge and experience weeds that are important to enables significant savings. weed species in Scotland have developed resistance to the sulfonylureas. biodiversity The table shows that control of some Reduced rates of autumn applied weed species can be maintained at Caution: Using lower rates than residual herbicides followed by the manufacturers label spring applications can reduce the recommendation is always at the cost of broad-leaved weed control in grower’s risk. winter cereals, particularly where it very low rates of the sulfonylurea Ally (20% w/w metsulfuron-methyl) at seedling stages under ideal trial conditions. Any gaps in the spectrum is necessary to treat perennial How can it help the environment? • Reduced amount of herbicides in at such low rates may be made up SAC herbicide screen 1997 – percent control of broad-leaved weeds at the four leaf stage in spring barley the environment • • Chickweed May enable the survival of less Field pansy Black bindweed Oilseed rape 30g/ha Ally 100 98 100 99 important to biodiversity 15g/ha Ally 99 100 93 100 Potential reduction in insecticide 7.5g/ha Ally 100 100 93 100 use resulting from increased 3.75g/ha Ally + 98 100 100 100 numbers of insect pest predators 0.25l/ha Deloxil SAC competitive weeds that are 57 23 Crop Protection section 2 Crop Protection Appropriate Herbicide Use by tank-mixing with other herbicides as shown in this example with Deloxil, Technical tip a 400g/l mixture of bromoxynil and ioxynil. Weed control at lower than Note: The efficacy of most soil acting herbicides is reduced by application to recommended label rate is dry soils (even with rain imminent). Foliage acting herbicides are most dependent on many factors. effective when applied to small weeds that are actively growing because of There is less scope to reduce moist soils and warm days and nights; however, note that some herbicides rates when faced with have a minimum weed size. difficult-to-control weeds in difficult conditions. How much will it cost you? Capital cost No capital investment required Operating cost No additional operating costs where crops - are regularly monitored. Increased knowledge may be required. Cost benefits Some savings compared with standard practice 58 - Further information • • • • • • BASIS qualified advisers AIC AICC HGCA SAC Weed Resistance Action Group Technology links • • Decision Support Systems • • • • Pesticide Mixtures Appropriate Active Ingredient Use Patch Spraying Appropriate Spray Quality Mechanical Weed Control 24 Crop Protection section 2 Crop Protection Appropriate Fungicide Use What is it? Appropriate fungicide use involves the tailoring of the use of fungicides to suit the crop situation and varieties grown i.e. the appropriate rate required to achieve good disease control whilst safeguarding application will also have an impact Fungicides differ in their activity on disease type and severity. depending on whether they are However, prediction schemes are applied before or after the disease is widely used to inform farmers, for present in the crop. All fungicides example when blight programmes are more effective when applied as a should commence and intensify in protectant (i.e. applied before the potatoes or when there is need for plant has been infected) than they fungicide application in oilseed rape. are when applied as an eradicant yield and crop quality. This approach requires knowledge of the factors (i.e. applied after the plant has been Fungicides are approved in cereals infected). Using dose response on the basis of single applications, curves helps in the selection of the but in practice farmers use two or appropriate fungicide for a given three applications. This, along with disease pressure. Tank mixtures of How can it help you? the fact that tank mixtures are often both protectant and eradicant employed, that some diseases are fungicide may be required where a • • Reduced fungicide costs more susceptible than others to a disease has already started to Helps with adherence to quality fungicide and that disease pressure develop. assurance and processors’ and varietal resistance vary from protocols site to site, enables rates below Appropriate fungicide use in the those recommended on the label to major cereal crops has been well be used. The same opportunity to researched and treatment reduce rates does not exist when programmes are readily produced using fungicides for blight control in each year. There is concern about potatoes, but may exist in other fungicide resistance (Septoria tritici broad-acre crops, particularly where to the strobilurins in cereals and How can it help the environment? sequences or tank-mixes are used. phenylamide resistance in potato Attitude towards risk and disease blight) and hence it is important to resistance management are also consider mixtures alongside • Reduced amount of fungicides in important factors to take into appropriate doses. HGCA-funded the environment account. experiments have shown poor that encourage disease development such as varietal resistance, rotation and weather conditions. Caution: Using lower rates than the manufacturers label recommendation is always at the grower’s risk. • control of Septoria tritici by May allow less frequent Crop quality specifications can be strobilurins in 2003; however affected by fungicide use, but mixtures with triazoles gave good Availability and use appropriate rates should provide disease control (see figure over). Thresholds and disease prediction monitoring is required for successful programmes should be used control, and timing of applications is pragmatically and within a risk critical for the successful use of management process. Use of current reduced rates. Treatment at early weather conditions may provide a stages of disease development can guide to the types of disease to be also be important for many diseases expected in cereals. Unfortunately, (e.g. mildew in wheat). applications of fungicides weather conditions occurring after reliable disease control. Regular crop 59 24 Crop Protection section 2 Crop Protection Appropriate Fungicide Use Comparison of disease control from treatment with a triazole, strobilurin and a mixture of the two. Technical tip Dose response curves for a 70 range of fungicides in wheat are published by HGCA: use these to assist in the 60 selection of appropriate fungicide rates in your programmes. Use reduced rate fungicide mixtures to guard against resistance 40 developing. Strobilurin 30 20 Triazole 10 Mixture 60 0 0 0.25 0.5 0.75 1 Dose Further information Wheat disease management 2004, HGCA Septoria tritici (%) 50 • • • • • • • BASIS qualified advisers AIC AICC BPC HGCA SAC Fungicide Resistance Action Group Technology links Note: The use of targeted rates of chlorothalonil in fungicide mixtures help to safeguard the performance of both triazole and strobilurin fungicide chemistry. How much will it cost you? Capital cost No capital investment required Operating cost No additional operating costs where crops - are regularly monitored. Increased knowledge may be required. Cost benefits Significant savings compared with standard practice - • • • • • Variety Choice • • • Pesticide Mixtures Novel Seed Treatments Crop Diagnostics Decision Support Systems Appropriate Active Ingredient Use Patch Spraying Appropriate Spray Quality 25 Crop Protection section 2 Crop Protection Appropriate Insecticide Use What is it? Appropriate insecticide use involves the tailoring of the rate and use of insecticide whilst providing economic control of insect pests. This requires regular crop monitoring and knowledge of economic thresholds. Such an approach can also aid the survival of predators of insect pests allows targeting of pests at an No synthetic insecticide is inherently earlier stage, using reduced rates or immune from resistance. Esterase targeted methods of application, and MACE resistance, which is such as new seed treatments for potentially very serious for seed wheat bulb fly or BYDV control. This potato growers, exists within aphid is also important for problem pests populations. A sensible resistance such as aphids which can infect management strategy is essential crops with plant viruses and where using products with different modes the problem can only be controlled of action in tank mixtures or in a protectant manner. sequences at appropriate rates but this often requires careful choice of insecticide as well as using an appropriate rate. within a carefully planned Good spraying conditions will allow programme. lower rates to be effective. A little How can it help you? moisture on the leaf surface can Advice on the manufacturers label increase uptake, and the correct should be followed and on occasions • • Reduced insecticide costs spray quality should always be used. where reduced rates are appropriate, Helps to maintain predator levels Fine sprays applied in low drift advice should be taken from a and hence reduce necessity for conditions can be most effective for BASIS-qualified agronomist. repeat treatments, i.e. reduced aphid sprays on the ears of winter Inappropriate dosing can lead to spray passes through the crop wheat, whereas coarser spray resistance problems developing. droplets are more appropriate for Caution: Using lower rates than the manufacturers label recommendation is always at the grower’s risk. soil-applied insecticides (e.g. Note: Difficult pests require high chlorpyriphos for leatherjacket water volumes and this is probably control). as important as the rate of product applied. Careful choice of product and rate How can it help the environment? will enable the more specific • Reduced amount of insecticides in Many of these are important to the the environment animals higher in the food chain Reduced impact on beneficial (e.g. birds) and/or are predators of insects that contribute to the food the target insect pest. This, along supplies of animals higher in the with cultural control measures, may food chain reduce insect problems in the future. • targeting of the pest and may allow the survival of non-target insects. Availability and use Applications of broad spectrum Thresholds for application are widely biodiversity in late spring and available for most insect pests. summer and should be avoided. Crops should be regularly monitored Particular care needs to be exercised at the appropriate time and when applying products hazardous applications made as soon as to bees. Crops in which bees are possible after thresholds are foraging should not be treated and exceeded if spraying conditions are local beekeepers should be notified acceptable. Timeliness in application well in advance of application. insecticides are most damaging to 61 25 Crop Protection section 2 Crop Protection Appropriate Insecticide Use How much will it cost you? - Technical tip Capital cost No capital investment required Operating cost No additional operating costs where crops of pirimicarb or the careful are regularly monitored. Increased knowledge selection of pyrethroid may be required. Cost benefits Some savings possible compared with standard practice - Use of the appropriate dose product, applied as soon as the threshold for aphids in the ears of wheat is reached, will provide economic control and should enable the survival of many non target species. Using relevant Environmental Information Sheets can give a useful guide to environmental performance. Further information 62 • • • • • • • • • BASIS qualified advisers • British Beekeepers Association • Insecticide Resistance Action AIC AICC BPC HGCA SAC SASA SCRI CPA – Voluntary Initiative literature on insecticide use and Environmental Information Sheets Group Technology links • • • • Novel Seed Treatments • • • Pesticide Mixtures Monitoring Pest Activity Decision Support Systems Appropriate Active Ingredient Use Patch Spraying Appropriate Spray Quality 26 Crop Protection section 2 Crop Protection Pesticide Mixtures What are they? Availability and use These are mixtures of pesticides Pesticide mixtures can be integrated (herbicides, fungicides and/or into existing programmes easily. insecticides) usually added together Manufacturers and distributors at lower than label recommended produce compatibility lists for their rates to produce better overall products and recommended tank performance against a variety of mix partners. Use of this information problems. Pesticide mixtures are will help avoid using mixtures that also a useful way of protecting are physically incompatible and/or individual active ingredients against where one partner reduces the the development of resistance. They efficacy of another partner. Caution: There may be some reduction in efficacy of one of the partners in some combinations (e.g. some grass weed herbicides mixed with the hormone or sulfonylurea herbicides) and there are sometimes restrictions on the time interval allowed between the applications of products in order not to compromise efficacy. usually give an improved spectrum of control compared with the Currently, the only legal restrictions individual pesticides used on their on tank mixing in the UK are that own. two or more anti-cholinesterase pesticides should not be mixed, How can they help you? • • Reduced pesticide costs all components of a tank mix should be used within their conditions of approval. Improved overall weed, disease and insect pest control • unless expressly permitted and that There are many examples of Help reduce risk of resistance pesticide mixtures that, by acting build up additively, work better than the individual component alone. It is How can they help the environment? • Reduced amount of pesticides in the environment very important, for instance, to have cyanazine (Fortrol) included with bentazone + MCPB or MCPA + MCPB in pea crops to enhance the activity of the partner product. The use of hormone herbicides, such as mecoprop, mixed with sulfonylurea herbicides, such as metsulfuronmethyl may minimise the development of sulfonyl resistant chickweed already found on a few Scottish farms. The use of targeted rates of chlorothalonil in fungicide mixtures is important to safeguard the performance of both triazole and strobilurin fungicide chemistry. 63 26 Crop Protection section 2 Crop Protection Pesticide Mixtures How much will it cost you? Technical tip Capital cost No capital investment required - Fungicide mixtures are Operating cost Extra management input may be required £ increasingly important to Cost benefits Potential savings by using reduced rates of partners protect against the development of resistance of Septoria tritici to the strobilurins. Inclusion of appropriate rates of triazole and chlorothalonil enhances the eradicant and protectant activity offered by the strobilurin and may reduce the development of resistance. Further information 64 • • • • • • • • BASIS qualified advisers • Fungicide Resistance Action Group • Insecticide Resistance Action Group AIC AICC CSL Liaison on-line service HGCA SAC The UK Pesticide Guide Weed Resistance Action Group Technology links • Appropriate Active Ingredient Use • • • Appropriate Herbicide Use Appropriate Fungicide Use Appropriate Insecticide Use 27 Crop Protection section 2 Crop Protection Pesticide Handling Systems What are they? Pesticide handling systems reduce the risk of spillage by improving the process by which pesticides are transferred from the original container to the sprayer tank. Spillages of concentrated pesticide Caution: When using closed Closed transfer systems remove transfer systems it is important the need to manually pour pesticide that systems are well maintained from the original container into the and operated in accordance with sprayer and hence substantially manufacturers instructions. reduce the risk of operator and Failures with this type of environmental contamination from equipment can result in major splashing and spillage. Most systems pollution incidents. use specialised connectors on both formulations, particularly when loading the sprayer, represent an important risk of both operator and the pesticide container and on the Availability and use point source environmental Induction hoppers will enable the contamination. Small volumes of the sprayer to be loaded with chemical concentrated formulation that are by an operator standing on the associated, for example, with the ground. They are widely available for residues on foil caps or washings use with all designs of sprayer. All from a pair of gloves used when new sprayers should incorporate an handling concentrated liquid induction hopper. Hoppers are also products can result in substantial available from specialist companies contamination of surface waters. To and can be retrofitted to most minimise the risk of such sprayer designs. There needs to be a contamination, two approaches are good working clearance around the currently available: induction opening of the hopper; this opening hoppers and closed transfer must be large enough so that there systems. is minimum risk of spillage or splashing. Ensure that the induction How can they help you? • with British Standard BS 6356: Part Reduced problems associated with advantages in terms of the speed of loading and ease of cleaning of both the hopper and used containers. • • Reduced risk of operator In most designs of induction hopper, contamination material poured into the hopper is Reduced spillage risk drawn into the main sprayer tank by Improved loading accuracy How can they help the environment? • • operated in conjunction with conventional standardised containers and so place no restrictions on chemical packaging and supply. Other systems require that the chemical is delivered in a specified container fitted with the appropriate coupling. Closed transfer systems encourage the use of returnable containers and this reduces the requirement to rinse containers and dispose of the washings. Compliance with British Standard BS 6356: Part 9: 1996 will help ensure that transfer and safety performance meet defined criteria. the action of a Venturi valve. Streams of water are directed down the side-walls to prevent material build up in the hopper; being able to important aspect of the performance surface water contamination of induction hoppers. A mechanism problems part packs must have some way of measuring the quantity of pesticide the graduations in the hopper will generally be too coarse for accurate measurement. Use a measuring jug or calibrated container. For closed transfer systems, some form of accurate measurement system will need to be incorporated. work with high loading rates is an Reduced risk of groundwater and Reduced packaging disposal Systems designed to operate with transferred. For induction hoppers, washing out pesticide containers • closed transfer systems can be 8: 1996; this will provide further Easier handling and loading of sprayers • hopper on your sprayer complies connection to the sprayer. Some for rinsing empty pesticide containers to a recognised standard must be incorporated into the hopper design. For returnable ‘key’ type containers, the Micro Matic ‘Drum Valve’ has now become the industry standard coupling. 65 27 Crop Protection section 2 Crop Protection Pesticide Handling Systems For low level filling and container rinsing Technical tip Knight Farm Machinery Ltd Systems meeting British Standards are likely to give better performance – ask your supplier which designs meet the requirements of the standard. Further information Induction hopper Silsoe Research Institute 66 Standardised (Micro Matic) coupling How much will it cost you? Capital cost cost if sprayer not fitted with well-designed £ Closed transfer systems – some capital cost for system and container interface. • • Chemical manufacturers • • • • • ADAS Cherwell Study British Standard BS 6356, 1996, Parts 8 & 9 Equipment manufacturers’ information CSL Pesticide Usage Report AEA AIC AICC ££ Technology links • Appropriate Active Ingredient Use • Sprayer Control and Maintenance • Improved Formulation and Packaging Induction hoppers – no increase in operating cost. Savings may come from reduced loading and container washing time. - Closed handling systems – speed and ease of operation are critical. Some designs slow the loading process. Cost benefits BCPC Monograph Induction hoppers – some small increase in hopper. Many now meet the required standard. Operating cost • • Induction hoppers – a small investment will give substantial improvements in pesticide handling Closed transfer systems – costs are higher than for an induction hopper but benefits are potentially greater. £ 28 Crop Protection section 2 Crop Protection Sprayer Control and Maintenance What is it? Sprayer control systems ensure How can it help the environment? the correct volume of spray solution • is delivered to the target. These systems allow precision farming Reduced amount of pesticides in the environment • Reduced contamination of field techniques to be used (e.g. variable margins, groundwater and surface rate application technology). The water from direct over-spraying in control system should also (i) allow ‘difficult’ shaped field, and sections of the boom to be turned priming and washing of the on/off without changing the pressure sprayer in the other operating sections; and (ii) adjust the output from the • pollution incident from machine or nozzles to apply a constant volume when operating over a range of forward speeds. Maintenance of the sprayer on a regular basis is essential to avoid breakdowns and spillages of dilute pesticide, as well as ensuring accurate application rates at all times. How can it help you? • • • • • Improved operation in awkward- that is washed out when cleaning out the sprayer is minimised. The ability to switch off small sections of the boom is particularly important to help avoid overlapping applications and help protect field boundaries and watercourses. Electronic control systems will also provide information on parameters Systems for re-circulating spray Availability and use Sprayer control systems All new sprayers are generally equipped with a relatively high level of control equipment. Control systems can also be purchased from specialist manufacturers and operate but some may require specific operator training. Recently developed control systems have facilities for • circulating spray liquid within the boom plumbing system so that Provide feedback information on priming of the nozzles at the what has been treated and beginning of a spraying operation chemical use requires less output of spray Potential for improved timeliness liquid; breakdown so that the quantity of pesticide total quantity of pesticide used. shaped fields of application from reduced risk of completion of a spray operation such as the total area treated and systems are relatively easy to Easier priming and emptying lines back into the tank at the component of record keeping retrofitted to sprayers. Most control Reduced overdosing on overlaps sucking liquid within the spray Can provide an important pesticide delivery procedures • system failure Accurate control of rate of and headlands when turning • Reduced risk of a point source • liquid and providing suction to recover liquid from the boom are specialised and only available from a limited number of suppliers. 67 28 Crop Protection section 2 Crop Protection Sprayer Control and Maintenance The diagram shows the layout of the plumbing arrangement for a boom Technical tip sprayer incorporating ‘suck-back’ facilities. Care is needed to minimise Re-circulating Spraying the range of speeds that the sprayer controller is expected Knight Farm Machinery Ltd Line Agitation System with Environmental Re-circulation to compensate for in order to maintain good delivery conditions. Use of multiple nozzle holders allows quick and easy selection of the correct nozzle to improve spray targeting and reduce the risk of spray drift. Caution: The use of an electronic control system will aid but not replace the need for sprayer calibration. Maintenance Further information • Code of Practice for the safe use of pesticides on farms and holdings. MAFF (under revision) • • • • • Manufacturers literature Sprayer testing can be undertaken by a test centre under the UK National 68 Sprayer Testing Scheme (NSTS). The NSTS was introduced to support the Voluntary Initiative. The test is conducted by an independent examiner who holds a valid NPTC Certificate for Sprayer Examiners. It covers the delivery system, the application system and ancillary equipment. A list of all test centres in the UK is available from NSTS. How much will it cost you? Capital cost AEA NSTS and monitoring ££ Technology links Re-circulation and suck-back facilities ££ • • • • • • • should enable equipment to last longer - Control systems – there should be no increase in operating costs and some savings in pesticide use - Maintenance – small cost of maintenance and testing to be recovered by savings in pesticide use Cost benefits AICC Control systems – recording, control Maintenance – involves no capital cost and Operating cost AIC Control systems – all will give advantages but cost:benefit will depend on options taken Maintenance and testing involves a small cost to give large potential benefits - Pesticide Handling Systems Patch Spraying Air Assisted Spraying Twin Fluid Nozzles Rotary Atomisers Low Volume Spraying Low Volume Washing Systems 29 Crop Protection section 2 Crop Protection Patch Spraying What is it? • component of record keeping Patch spraying aims to adjust the application of pesticides to match localised conditions and account for in-field variability. Much of the work to develop these systems has been Can provide an important weeds in cereal crops. Selective herbicides for grass weeds are relatively expensive. There is Availability and use use GPS for in-field location. Any patch spraying approach will Some components of an automated, require: high-resolution patch spraying system will be common with other • • evidence to show that grass weeds such as wild oats, couch and black grass occur in patches that are relatively stable both from season to • a method of detecting weed, components of a precision farming disease or other target patches system. a means of in-field location for defining the position of patches For high-resolution automated and for directing the application systems, it has been shown that system weed patches can be mapped a decision making module that season and within a season. Patch defines the total area(s) to be spraying with high/low rate treated, the mixture of pesticides applications can give good levels of to be used, the rates and method control with reduced pesticide use of delivery and the control of weeds is sustained in subsequent seasons. pressure control and combinations of these); these systems now mainly done to improve the application of selective herbicides to control grass (injection metering, on/off control, • manually from a range of types of vehicles (e.g. using ATVs early in the growing season through to mapping from the combine harvester). This map then needs to be transformed into a treatment map. This will a means of applying the account for weed seed movement treatment. between mapping and treatment, Patch spraying can also use different positional errors and the response pesticide mixtures and/or deliver Patch spraying can be implemented sprays with different forms to match automatically using systems target requirements across a field or employing in-field location A key factor relating to the in different parts of the same field. equipment such as a Global treatment system is the range of Positioning System (GPS). Simpler rates that can be delivered while approaches with large-scale maintaining the required physical resolution can be operated with characteristics of the spray. This is existing equipment (e.g. treat one because a dual-rate strategy will half of the field with a different rate require a low rate in field areas or pesticide mixture from the other where weed pressure is low and a half). Simple hand drawn field maps higher rate where there is a defined can also be useful when used in weed or disease problem. An conjunction with careful field analysis of such systems has monitoring. The approach to use indicated that a rate range of at depends on the scale, resolution and least 3:1 is required. This cannot be degree of automation that is achieved by conventional pressure appropriate for your particular farm. control systems but is possible with How can it help you? • • Reduced pesticide costs Potential for improved and automated record keeping, demonstrating compliance with crop assurance schemes, codes of practice and LERAP regulations • Reduced risk of damage to sensitive adjacent crops such as potatoes • Reduced risk of prosecution due to spray drift How can it help the environment? • Reduced amount of pesticides in the environment • function of the application system. twin-fluid nozzles, rotary atomisers At the largest scale, patch spraying and with combined on/off and can be done by treating sections of pressure control units. These are all fields with conventional equipment. available commercially. At the smallest resolution and with the highest level of automation, a number of systems are commercially Reduced surface water and available using different approaches groundwater pollution to adjusting sprayer output 69 29 Crop Protection section 2 Crop Protection Patch Spraying Example of a treatment map Technical tip Many automated systems for 19980018 patch spraying can also be Field name Area : Elmdon : 8.4 ha used to provide targeted Implement : Patch Sprayer application of liquid Product : Fungicide fertilisers. Std. app. rate : 3 litres/ha Grid size : 24 m Further information • Equipment manufacturers – sprayers and control equipment • Precision farming of cereals: practical guidelines and crop nutrition, 2002. HGCA • • • • • AEA App. amount needed: litres 5 litres/ha 4 litres/ha 3 litres/ha 2 litres/ha 1 litres/ha 3 litres/ha Silsoe Research Institute 70 33 Useful savings and efficacy improvements can be made by treating headland areas or areas near trees with different pesticide rates. Potential herbicide savings are less where serious patchy grass weeds are not a problem. AIC AICC SAC The Precision Farming Alliance How much will it cost you? Technology links Capital cost • • • • • Electronic Communication • • • Twin Fluid Nozzles High resolution – specialised equipment is to be used for mapping, treatment map generation and application equipment ££ Lowest resolution – can be implemented with existing equipment but benefits will be lower Operating cost - High resolution – higher technical input is required to operate highly automated systems. However, operating costs will be reduced due to savings in pesticide use. - Lowest resolution – there is a cost associated with mapping but this should be more than recovered by savings in pesticide use Cost benefits Cost benefits depend on level of resolution and weed, disease or other target patch distributions – can involve both high investment and large savings - Appropriate Herbicide Use Appropriate Fungicide Use Appropriate Insecticide Use Sprayer Control and Maintenance Rotary Atomisers Yield Mapping 30 Crop Protection section 2 Crop Protection Appropriate Spray Quality What is it? Availability and use ‘Spray quality’ describes the droplet The spray quality required when size distribution in the spray applying a particular pesticide will produced by a nozzle. Spray depend on the mode of action and qualities of very fine, fine, medium, the mechanisms of uptake by the coarse and very coarse are defined target. Most pesticides will give the in the International BCPC best coverage and retention when classification scheme in comparison applied as a fine spray unless with a reference nozzle. The spray penetration into the crop canopy is quality produced by any nozzle important to the mode of action. system depends on the type of The need to both control drift and nozzle, the orifice size, spray angle give some penetration of the crop and operating pressure. Choosing means that a medium spray is most the appropriate spray quality to commonly recommended. information to aid nozzle selection for cereals and oilseed rape is also available in the HGCA Nozzle Selection Chart. For conventional flat fan hydraulic pressure nozzles, the following simple relationships apply: • wider fan angles give finer sprays • smaller nozzle sizes of a given angle give finer sprays • increasing spray pressure gives finer sprays match the mode of action of the pesticide will give the highest Characteristics of the main spray qualities efficacy and allow the minimum dose to be used. Spray quality will also provide an indication of the risk of drift (with finer sprays leading to higher levels of drift). Other factors Spray Relative Spray Penetration quality coverage Retention of canopy 1 Fine Drift risk 71 Very good Low High Good Good Moderate Moderate/poor High Low such as droplet speed, wind speed and trajectory angles will also Medium 2 influence the risk of drift. Coarse 1 /3 /2 How can it help you? • • Enables optimal use of pesticides Choosing and using the appropriate Spray quality can only be used as an spray quality is relatively indicator of the risk of drift. Fine straightforward. Many pesticide sprays will tend to drift unless labels will specify the spray quality constrained in some way. Some to be used for application. Where medium quality sprays can also pose Reduced risk of spray drift onto spray quality specifications are not high drift risks if released slowly and non target areas such as adjacent provided, using a medium spray with a predominantly horizontal crops quality is generally acceptable. trajectory. It is likely that Where tank mixes involve products nozzle/spray classification schemes with different spray quality in the future will be extended to requirements, use a nozzle which is include a direct assessment of drift appropriate to all of the products. risk but such approaches have not Enables the balance between efficacy and drift control to be considered in all application situations • How can it help the environment? • Reduced amount of pesticides in the environment • yet been established. Where Nozzle manufacturers produce charts possible, obtain information about Reduced contamination of that show spray qualities for drift risk that is independent of hedgerows, field margins, different nozzle designs, sizes and spray quality information. groundwater and surface water operating pressures. Additional 30 Crop Protection section 2 Crop Protection Appropriate Spray Quality How much will it cost you? Capital cost Technical tip Small capital cost involved so as to provide Vertical or small targets (e.g. an appropriate range of nozzles from which to choose grass weeds) are generally £ best covered with a fine Multiple nozzle turrets involve a small cost quality spray, whereas increase but make changing nozzles easier horizontal or large targets and quicker £ (e.g. soil applied residual herbicides) are best applied Operating cost Small increase in costs associated with using a coarse spray using the correct spray quality but potential savings in pesticide use Cost benefits Small cost of nozzles gives benefits to the user and the environment 72 Further information • • Pesticide labels • Nozzle Selection Chart, 2002. HGCA • Sprayer calibration procedures included in publications by BCPC and CPA • • AIC Nozzle manufacturers’ data sheets AICC Technology links • • • • Appropriate Herbicide Use • • • • • Air-Assisted Spraying Appropriate Fungicide Use Appropriate Insecticide Use Drift Reduction by Nozzle Selection Air Induction Nozzles Twin Fluid Nozzles Rotary Atomisers Low Volume Spraying 31 Crop Protection section 2 Crop Protection Drift Reduction by Nozzle Selection What is it? Availability and use Careful sprayer nozzle selection Most manufacturers of agricultural optimises efficacy whilst reducing spray nozzles offer both pre-orifice risk of spray drift onto non-target (low drift) and air induction nozzles areas. Much of the emphasis relating as part of their range. Twin-fluid to spray nozzle design over the last nozzles and rotary atomisers are decade has been directed at available from specialist suppliers. on the results from field tests) or nozzles (based on the results from delivering reductions in the risk of wind tunnel evaluations). The star ratings are comparative measures based on drift reductions compared with a reference system, i.e. a conventional 110° flat fan nozzle operating on a 12m boom at a pressure of 3.0 bar and a flow rate drift. Three main nozzle types have With any nozzle design, the risk of been shown to deliver drift reduction drift will be a function of design when compared with conventional parameters (e.g. spray angle – for a hydraulic pressure nozzle designs. given size of conventional nozzles, Pre-orifice (low drift) and air wider angles give finer sprays which induction nozzles fit into standard increases the risk of drift) and nozzle nozzle holders on the sprayer and size (smaller sizes of conventional operate with pressurised liquid only. nozzle give finer sprays and an Twin-fluid nozzles require a increased risk of drift). per nozzle of 1.2l/min. The star ratings are then defined in relation to this reference as follows: 1 Star (*) = drift less than 75% of the reference 2 Star (**) = drift less than 50% of the reference specialised holder and a compressed air supply. Rotary atomisers require Studies have also shown that the specialised fitting and an electrical same nozzle specification (e.g. in supply. terms of flow rate at a given pressure and nominal spray angle) How can it help you? • Provides a basis for selecting nozzles that will minimise drift while maintaining efficacy • from different manufacturers can give different levels of drift risk. There is a need therefore to provide users with information relating to the risk of drift from different nozzle Enables reduction to as little as 1m for the size of buffer zones designs, sizes and operating pressures. used to protect water from spray drift contamination under the LERAP rules Assessment for Pesticides (LERAP) How can it help the environment? • Reduced amount of pesticides in and nozzles that gives a direct the environment indication of the drift-reducing Reduced contamination of field margins, hedgerows, groundwater and surface water Pesticides Safety Directorate defines a star rating scheme for sprayers capability of an application system when compared with a conventional boom and flat fan nozzle arrangement. The scheme applies to Caution: Nozzle performance and the risk of spray drift are also influenced by the physical properties of the spray liquid. of the reference Details of sprayers and nozzles that have achieved given LERAP star ratings can be found at www.pesticides.gov.uk. Note that the awarding of a LERAP Low Drift star rating is for a particular design of nozzle at a given height, operating pressure, forward speed and operating condition. When The Local Environmental Risk scheme administered by the • 3 Star (***) = drift less than 25% complete spraying systems (based nozzles with a given star rating are fitted to a boom sprayer with a conventional design, then the complete sprayer takes the same rating as for the nozzles. Note that LERAP Low Drift three star ratings can only be achieved with nozzles operating at low air input pressures (typically <0.5bar). 73 31 Crop Protection section 2 Crop Protection Drift Reduction by Nozzle Selection Most nozzle systems obtain a LERAP Low Drift star rating from results Technical tip collected in wind tunnel conditions. The graph shows measured downwind profiles of sedimenting spray drift captured on sampling lines in a wind The use of multi-nozzle turret tunnel test. This type of data is used when determining LERAP Low Drift star holders enables drift- ratings for nozzles. The results for the different nozzle designs operating at reducing nozzles to be the same pressure and flow rate show: selected when operating • close to the field boundary the high level of drift reduction that can be achieved by air induction nozzles leading to LERAP Low Drift three star ratings • an increase in drift from flat fan nozzles when spray fan angle is o o increased from 110 to 120 • the levels of drift reduction achieved by pre-orifice nozzles are less than those from air induction designs Horizontal airborne spray profiles for different designs of flat fan pressure nozzle 74 16.0 12.0 10.0 8.0 6.0 4.0 2.0 0.0 2.0 3.0 4.0 5.0 6.0 7.0 Distance downwind, m Conventional flat fan - 120 deg. Pre-orifice flat fan - 120 deg Air-induction flat fan - 120 deg. Reference flat fan 110 deg. From Miller & Lane, Aspects of Applied Biology, 1999 Airborne spray, % of nozzle output 14.0 31 Crop Protection section 2 Crop Protection Drift Reduction by Nozzle Selection Comparative information relating to the risk of drift from different nozzle designs operating in conjunction with conventional boom sprayers can be obtained from the HGCA Nozzle Selection Chart. This guide also gives comparative information relating to efficacy when treating different targets Further information • • Manufacturers data • • PSD web page on LERAPs • • • CPA – Voluntary Initiative with a range of nozzle types. The International BCPC nozzle classification system is likely to include a measure of drift risk assessment but this is yet to be well established. How much will it cost you? Capital cost Small increase in capital costs due to the need to purchase additional drift-reducing nozzle sets Operating cost No increase in operating costs. Reducing the width of the buffer zone may improve returns. Cost benefits Important benefits in return for small cost of nozzles £ LERAP Guide for Horizontal boom sprayers. Defra Nozzle Selection Chart, 2002. HGCA AIC AICC Technology links • • • • • • Appropriate Spray Quality Air-Assisted Spraying Air Induction Nozzles Twin Fluid Nozzles Rotary Atomisers Low Volume Spraying 75 section 2 76 32 Crop Protection section 2 Crop Protection Air-Assisted Spraying What is it? Availability and use Air-assisted spraying uses relatively A number of the major European large volumes of low-pressure air, sprayer manufacturers build models for example generated by a fan, to that are specifically designed to direct spray into the crop. The carry a flexible air duct along the system aims to give good control of boom. The flexible air duct is spray drift when using conventional supplied with air from an axial flow nozzles. Penetration into the crop fan. Air can be delivered from an canopy and improved coverage on array of holes or from a slot. Most shaded targets, such as the air-assisted sprayers of this type undersides of leaves and stems enable adjustment of the quantity of when spraying for blight control in air that is delivered along the boom, potatoes, is also made possible with and sometimes adjustment of the this type of application system. In delivery angle. Where air-assistance most designs, air is transported is not a design option, systems are along the spray boom in flexible available for retro-fitting to most ducts. The shape of the duct and the types of boom sprayers. The figure over shows the improvements that can be achieved in reducing drift at different wind speeds by using air-assisted spraying when compared with a conventional system. As expected, drift increased with wind speed; adding air-assistance reduced the level of drift by more than 50% at the lower wind speeds and up to 65% in the higher winds. baffles inside each duct are designed to give uniform air delivery along the Operators need to be aware of the boom. importance of using the correct setting for the operating, weather How can it help you? • Increased penetration into dense canopies and increased coverage on shaded targets • and crop conditions associated with each application. Training is essential to be able to optimise use. A separate module in the NPTC scheme for spray operators covers Potential improved timeliness air-assisted sprayers. from use of low volumes • Enables fine sprays without The improved drift control available increasing risk of drift with air-assisted sprayers means that this type of machine can How can it help the environment? • Reduced amount of pesticides in the environment • Reduced contamination of field margins, hedgerows, groundwater and surface water achieve LERAP Low Drift star ratings when operating with conventional nozzles that otherwise do not have a LERAP Low Drift star rating. 77 32 Crop Protection section 2 Crop Protection Air-Assisted Spraying Drift reducing capabilities of air-assisted spraying at different Technical tip wind speeds Care is needed when setting levels of air-assistance for Conventional Air assisted operation over sparse crop and/or bare ground. High 5 level of air-assistance in these conditions can lead to 4 crop damage in adjacent Drift % fields due to the increased risk of spray drift caused by 3 spray being ‘reflected’ off the ground 2 1 Further information Hardi International A/S 0 1.5 3 4.5 8.5 Wind speed, m/s 78 Speed = 7.7km/h Water volume = 100 l/ha Pressure = 2.5 bar How much will it cost you? Capital cost A spray vehicle with a larger power unit ££ • • ££ • Air-assistance increases power consumption and requires a higher operator skill level Cost benefits • • • • • the purchase of an air-assisted sprayer. Operating cost • Relatively high costs involved to deliver advantages relating to drift control and spray deposit targeting Sprayer manufacturers literature LERAP Guide for Horizontal boom sprayers. Defra PSD web page on LERAPs AEA AIC AICC Technology links Some increased investment associated with may also be required • - Sprayer Control and Maintenance Appropriate Spray Quality Drift Reduction by Nozzle Selection Low Volume Spraying 33 Crop Protection section 2 Crop Protection Air Induction Nozzles What are they? Air induction nozzles are designed to fit into conventional nozzle holders on sprayers. They generally create a spray with large droplet sizes and air inclusions that gives good control of spray drift. Each nozzle is made with two types of orifice – a flow metering orifice at the inlet to the nozzle and a final orifice at the outlet. Between these two orifices, there is an air inlet positioned so that, as a result of the Venturi effect, air is drawn into the nozzle acting materials such as some grass Caution: Sprays from air or broadleaf herbicides or those induction nozzles have spray products requiring good target droplets with ‘air inclusions’ – coverage such as strobilurin small bubbles of air within the fungicides. Some manufacturers droplets. After leaving the nozzle, specifically recommend not using they differ in behaviour compared this nozzle type with certain with the same size conventional pesticides: check the label and seek droplet. This means that the advice from a BASIS-qualified established spray classification adviser. Use of this nozzle type in a system does not apply directly to multi-turret nozzle holder in sprays from this type of nozzle conjunction with conventional design. hydraulic pressure nozzles enables the correct nozzle to be selected for any given application. behind the metering orifice. The nozzle design often includes an elongated mixing section so that these nozzles can look very different from conventional designs. How can they help you? • 79 A typical design of air induction nozzle Improved control of spray drift Silsoe Research Institute helping with compliance with LERAP requirements How can they help the environment? • Reduced amount of pesticides in the environment • Reduced contamination of field margins, hedgerows, groundwater Type of droplet structure generated by this nozzle design and surface water Availability and use All major conventional nozzle manufacturers include an air range of designs. There is some risk to product efficacy particularly when treating small plant targets with foliage Silsoe Research Institute induction flat fan nozzle in their 33 Crop Protection section 2 Crop Protection Air Induction Nozzles Recent research funded by HGCA has shown differences in efficacy between Technical tip different commercial designs of air induction nozzles particularly when treating small targets with foliage acting pesticides or where reduced rates Different designs of air of pesticide are used. Nozzles giving a smaller droplet size tended to give induction nozzles from higher levels of efficacy, but increase the risk of spray drift. different manufacturers give different droplet size distributions for the same nozzle specification. Data Comparison of blackgrass control achieved using different designs of from the manufacturers or air induction nozzles at different pesticide rates and growth stages from LERAP star ratings will help inform air induction nozzle selection % Control 100 Further information 95 • • Nozzle manufacturers. • LERAP Guide for Horizontal boom sprayers. Defra • • • • • PSD web page on LERAPs 90 80 85 2.5 l Hawk+Oil@1 leaf 1.25 l Hawk+Oil@1 leaf 2.5 l Hawk+Oil@2-3 leaves 1.25 l Hawk+Oil@2-3 leaves Treatment Nozzle 1 Nozzle 2 Nozzle 3 HGCA Report No.317 80 Nozzle Selection Chart, 2002. HGCA AEA AIC AICC SAC Conventional flat fan Technology links Nozzle 1 - gives a relatively small droplet size Nozzle 2 - gives a medium droplet size Nozzle 3 - gives a relatively large droplet size How much will it cost you? Capital cost Small increase in capital cost since these nozzles are more expensive than conventional designs £ Operating cost No increase in operating costs - Cost benefits Important gains in nozzle performance in relation to spray drift control delivered at relatively low cost • • Appropriate Spray Quality • Low Volume Spraying Drift Reduction by Nozzle Selection 34 Crop Protection section 2 Crop Protection Twin Fluid Nozzles What are they? Twin fluid nozzles use spray liquid How can they help the environment? and air both fed to the nozzle body • under pressure to create a spray. The air supply required to operate included droplets in the spray from twin fluid nozzles means Reduced amount of pesticides in the environment • Caution: The presence of air- that they differ in behaviour after leaving the nozzle compared with Reduced contamination of field the same size conventional this design of nozzle is usually margins, hedgerows, groundwater droplet. Therefore, the provided by a compressor mounted and surface water established spray classification on the sprayer. An important feature of this system is the ability to vary Availability and use nozzle output and spray quality independently for a given nozzle tip by varying the input pressures of both air and liquid. The nozzles can operate effectively at low volumes; sprays have droplets with airinclusions. Trials have shown that good control of drift can be achieved when compared with conventional Twin fluid nozzle systems use system does not apply directly to sprays from this type of nozzle design. specialised nozzle bodies and a compressed air supply. Therefore, The figure over shows increased they are commonly incorporated into deposition when using twin fluid complete spraying systems. Retro- nozzles compared with conventional fitting such a system onto a hydraulic nozzles. conventional sprayer is possible, but complex and costly. nozzles operating at the same flow rates. Drift reduction compared with conventional hydraulic pressure nozzles is achieved due to (i) the relatively large air-included droplets generated with appropriate settings, (ii) the downward current of air coming from the nozzle, and (iii) the mechanism of spray formation within the nozzle. Twin fluid nozzle systems are more complex to operate than conventional spraying equipment because of the need to set/adjust the pressures of both the air and spray liquid. However, nozzle manufacturers supply detailed charts giving flow rates and spray qualities for different air and liquid input combinations. Automatic control How can they help you? • • systems have been developed to maintain a given spray quality over a range of output flow rates. This Improved timeliness from use of enables effective compensation for low volumes speed changes over a wider range The ability to change spray than would be possible with quality and output rate on the conventional hydraulic pressure move can improve targeting and nozzles. helps to minimise pesticide costs • • Systems are less prone to nozzle The output from twin fluid nozzles blockage at low volumes than can be adjusted over a wide range equivalent conventional designs, (more than a factor of 3:1). This resulting in less downtime design is therefore useful in Improved control of spray drift helping with compliance with LERAP requirements targeting applications and patch spraying. 81 34 Crop Protection section 2 Crop Protection Twin Fluid Nozzles Spray deposition on grass weeds Technical tip Showing a comparison between twin fluid and conventional hydraulic nozzle Twin fluid nozzles can be very sensitive to pressure 60 settings. Ensure that gauges 50 are correct and pressure regulation/control systems 40 30 20 10 0 Twin fluid fine Twin fluid med 100L/ha F 100L/ha M 200L/ha F 200L/ha M 200L/ha C 400L/ha F Clodinafop mg/g 82 How much will it cost you? Capital cost Syngenta Crop Protection UK Ltd Mcg Clodinafop/gm fresh wt 70 are operating effectively. Further information • Nozzle and sprayer manufacturers • LERAP Guide for Horizontal boom sprayers. Defra • • • • PSD web page on LERAPs conventional sprayer both because of the ££ Operating costs for a twin fluid nozzle system are slightly higher than for a conventional unit because of the air supply Cost benefits Better use of pesticides may enable the higher capital and operating costs to be recovered AICC • Sprayer Control and Maintenance • • • Patch Spraying • Low Volume Spraying need to supply compressed air and because Operating cost AIC Technology links There is a higher capital cost than for a the nozzle bodies are relatively complex AEA £ Appropriate Spray Quality Drift Reduction by Nozzle Selection 35 Crop Protection section 2 Crop Protection Rotary Atomisers What are they? Rotary atomisers use the centrifugal How can they help the environment? energy created by a spinning disc, • cup or cage to create a spray, rather than using liquid pressure. The tight control over droplet sizes in the spray from rotary atomisers Reduced amount of pesticides in the environment • good performance. means that some of the defined spray qualities will not directly Reduced contamination of field match those from conventional Important features of this system margins, hedgerows, groundwater nozzles; this is why drift reduction is are the ability to produce a more and surface water achieved for the same nominal spray tightly controlled droplet spectrum quality. If very low drift levels are than pressure based nozzles, and Caution: Using very low volumes needed, low atomiser rotational the ability to maintain spray quality with rotary atomisers requires speeds must be used in order to over a large range of liquid flow careful choice of product and produce large spray droplets. rates at a particular atomiser spray quality. Spray rotational speed. Rotary atomisers behaviour/trajectory is different Because the output from rotary can operate effectively at very low from conventional hydraulic atomisers can be adjusted over a volumes. Trials have shown that pressure nozzles. wide range (more than a factor of good control of drift can be achieved when compared with conventional Availability and use nozzles producing the same spray quality. Rotary atomisers are usually either electrically or hydraulically powered. Rotary atomisers need special mounting brackets and additional electrical wiring/controls or hydraulic lines/valves and are therefore better How can they help you? • suited to being incorporated into a complete spraying system. Retrofitting such a system onto a The ability to closely control conventional sprayer is possible but droplet size and change spray complex. quality and output rate on the • • move improves targeting and Rotary atomisers are more complex minimises pesticide costs to operate and maintain than Improved timeliness and conventional spraying systems optimised pesticide use from use because of the need to set/adjust of low volumes atomiser rotational speed as well as Systems are less prone to liquid output. The atomisers are blockage than conventional relatively complex, have moving nozzles, resulting in less parts, and a reasonably high degree downtime and less risk of of maintenance is required to ensure operator contamination 3:1), this design is useful in targeting sprays better and in patch spraying. 83 35 Crop Protection section 2 Crop Protection Rotary Atomisers Deposition (µl cm-2 x 10,000) of fluorescein tracer after correction for application volume through a wheat crop at different growth Technical tip Rotary atomisers need to be stages from flat fan nozzles and rotary atomisers (±SE). well maintained. Ensure that the system is thoroughly Growth stage Sampling position Flat fan nozzles 200l/ha Rotary 20l/ha (fine quality spray) Rotary atomiser 40l/ha (medium quality spray) cleaned and basic maintenance is carried out at the end of each spray 31 39 59 84 70 75 77 Leaf 1 5 (1) 75 (5) 15 (1) Leaf 3 7 (1) 35 (4) 17 (6) Ground 9 (1) 44 (6) 21 (3) Flag 5 (0) 34 (2) 12 (1) Leaf 3 4 (1) 23 (1) 10 (0) Ground 2 (0) 10 (0) 9 (1) Ear 2 (0) 10 (0) 10 (0) 16 (1) Flag 3 (0) 12 (1) Leaf 3 2 (0) 13 (1) 13 (1) Ground 3 (0) 11 (0) 11 (0) Ear 9 (1) 6 (1) Flag leaf 26 (2) 30 (3) Leaf 1 25 (1) 26 (3) Ground 12 (1) 18 (2) Ear 15 (1) 24 (2) Flag leaf 26 (1) 60 (14) Leaf 1 23 (2) 17 (1) Ground 15 (1) 10 (1) Ear 30 (2) 19 (3) Flag leaf 30 (2) 30 (3) Leaf 1 20 (1) 20 (2) Ground 16 (1) 14 (2) From Holland et al., 1997 operation. 35 Crop Protection section 2 Crop Protection Rotary Atomisers Further information Using reduced volumes with rotary atomisers gives equivalent control to high volume applications, with large reductions in dosage rates possible against specific targets (see figure). Corrected cereal aphid mortality following application of deltamethrin at half (3.125g a.i./ha) and one twentieth (0.313g a.i./ha) of the full recommended dosage rate on winter wheat using rotary atomiser and flat fan nozzle sprays 100 Nozzle and sprayer manufacturers • • • AEA AIC AICC 90 Technology links 80 • Sprayer Control and Maintenance • • • Patch Spraying • Low Volume Spraying 70 Corrected % mortality • 60 50 40 Appropriate Spray Quality Drift Reduction by Nozzle Selection 30 References 20 10 0 0 2 4 6 8 10 12 From Holland et al., 1997 Days after treatment Micromax1/2 rate Micromax 1/20 rate flat fan 1/2 rate flat fan 1/20 rate Control mortality How much will it cost you? Capital cost There is a higher capital cost than for a conventional sprayer because of the need to power the atomisers and because of the complexity of the atomisers Operating cost ££ Operating costs for rotary atomiser sprayers are higher than for a conventional system due to maintenance requirements Cost benefits Better timeliness and better use of pesticides due to targeted low volume sprays should enable the higher capital and operating costs to be recovered £ Holland J.M., Jepson P.C., Jones E.C. and Turner C. (1997). A comparison of spinning disc atomisers and flat fan pressure nozzles in terms of pesticide deposition and biological efficacy within cereal crops. Crop Protection 16 (2), 179-185. 85 section 2 86 36 Crop Protection section 2 Crop Protection Low Volume Spraying What is it? Availability and use Low volume spraying is the use of The use of low volumes is easy to lower than typical or lower-than- implement with modern spraying label recommended water volumes equipment. Spray volumes can be for spraying, and is often referred to reduced by: as reduced volumes. It improves • 14km/h. If no changes are made to the nozzle selection, this results in a reduction in volume rate of between 20 and 45% when compared with travelling at 8km/h. Using nozzles with a lower flow work rates and hence timeliness. rate – the limiting factor on the Lower volumes tend to give a higher Conventional standard spray nozzle to be used is the risk of retention in the canopy although not applications to arable crops apply a drift from the smaller droplet necessarily higher efficacy. volume of 200l/ha from boom sizes produced by conventional Penetration into the canopy is sprayers travelling at 8km/h. hydraulic pressure nozzles. generally reduced with lower Substantial improvements in work However, this can now be volumes. rates can be achieved if sprays are overcome by using air assistance applied at lower volumes or by selecting a nozzle type The most important features of low (e.g. 100l/ha) because the time giving larger droplets for volume spraying are the taken per unit area sprayed to fill improved drift control (e.g. air improvement in work rates, the machine is reduced. induction, twin fluid nozzles or timeliness and reduced cost per unit rotary atomisers). area sprayed. The figures show how Increasing forward speeds during decreasing volumes and high Low volumes give higher work application – improved spray spraying speeds can increase work rates that in turn give vehicle design, and particularly rates. - improved timeliness and the improved boom suspensions, potential to use reduced rates have meant that many operators reduced capital and operating are now able to travel at 10- How can it help you? • - • 87 costs per unit area sprayed • Reduced problems with supplying Effect of volume (l/ha) on work rate water to the machine in field 7.0 6.0 • 5.0 Reduced risk of run-off from treated crop Caution: It is important to consider the risk of drift when using low volume applications and 4.0 3.0 2.0 1.0 not use low volumes if aiming to penetrate a dense crop canopy. This method of application is not 0.0 250 200 150 Application volume, l/ha recommended for some pesticides: read the product label carefully. 24 m boom 12 m boom 100 50 Silsoe Research Institute to select nozzles appropriately. Do Work rate, ha/h How can it help the environment? 36 Crop Protection section 2 Crop Protection Low Volume Spraying The effect of spraying speed on work rate Technical tip 6.0 As adjuvant rate is generally based on achieving a given Work rate, ha/h 5.0 concentration in the spray mix, reducing volumes 4.0 enables reduced rates of adjuvants to be used. 3.0 2.0 Further information Silsoe Research Institute 1.0 0.0 6.0 8.0 10.0 12.0 14.0 16.0 Spraying speed, km/h 12 m boom 24 m boom • Nozzle Selection Chart, 2002. HGCA • • • • • CPA publications Pesticide product labels AEA AIC AICC Research is currently examining the scope for reducing volume rates to less 88 than 100l/ha. Twin fluid nozzles and rotary atomisers allow volume rates as low as 50l/ha to be used in some circumstances. How much will it cost you? Capital cost Little capital cost involved. Good sprayer Technology links • Sprayer Control and Maintenance • • Appropriate Spray Quality • • • • Air-Assisted Spraying maintenance is important and it may be necessary to purchase additional or specialist nozzles. Operating cost Operating costs will be lower due to increased work rates and savings in pesticide use Cost benefits Better timeliness and better use of pesticides will give substantial benefits £ Drift Reduction by Nozzle Selection Air Induction Nozzles Twin Fluid Nozzles Rotary Atomisers 37 Crop Protection section 2 Crop Protection Low Volume Washing Systems What are they? Low volume washing systems reduce the need to use large quantities of washing water to clean out spray tanks by incorporating specially designed spray nozzles within the tank. This results in a lower volume If the tank is of an awkward shape lead to the formation of dried or has several compartments or deposits which are more difficult to internal baffles, multiple nozzles may remove at a later stage. be necessary to ensure complete Manufacturers guidelines should be coverage of the tank. Tank wash strictly nozzles can be plumbed into the adhered to. spraying equipment by fitting an extra line on the pressure side of the Two rinses with a small volume of pump. A valve can be installed so water are more effective in diluting that the line can be turned on and the spray residue than a single rinse off. An in-line filter is needed before with a higher volume. Tests have the washing nozzle to prevent any shown that two reduced volume How can they help you? debris affecting its operation. wash-outs with a sprayer cleaner will Consult the nozzle manufacturer for remove any sulphonylurea residues the recommended pressures, flow which might damage sensitive crops. • • • Reduced washing out problems rates and depth of placement within The effectiveness of this procedure Reduced sprayer cleaning time the tank. depends on starting with a clean Smaller volume of washings to In order to reduce significantly the dispose of risk of point source pollution, Reduced risk of chemical carry- decontamination of sprayers and over to the next spraying disposal of the dilute washings operation should be carried out in the field or of washings for disposal, and a reduced risk of spillage and point source contamination of surface and groundwater. • sprayer, free from sticky coatings or using a biobed, rather than onto How can they help the environment? • • concrete at the farm buildings. The principle of biobeds is to retain the dilute pesticides in a pit containing a Reduced amount of pesticides in mixture of materials that will enable the environment the active ingredients to decompose Reduced risk of groundwater and by a process of biodegradation. surface water contamination Some crops are extremely sensitive Availability and use Low volume tank washing systems are widely available. They are a standard fitting on many new sprayer designs and can be readily retro-fitted if they are not already part of the standard equipment on a to very small quantities of herbicides remaining in spray equipment from previous applications. It is therefore essential, after spraying, to clean the sprayer and all associated equipment (e.g. induction bowls and lances) to prevent damage to sensitive crops sprayed afterwards. sprayer. Following any herbicide application, Tank washing nozzles fit inside the an immediate rinse of the spray tank tank and come in two basic forms: with clean water is recommended to • • A fixed cluster of several nozzles dilute any chemical remaining in the A nozzle device which rotates machine. A full clean-out should be o through 360 done as soon as possible. Delay can visible residues. It is important to use the correct concentration of cleaning solution and to expose all surfaces to it. 89 37 Crop Protection section 2 Crop Protection Low Volume Washing Systems Components of a rotary tank washing system Technical tip Guidelines for low volume washing are now available for sulphonylurea herbicides. Low volume washing can reduce both the time taken and the volume of waste Silsoe Research Institute water produced when switching from applying cereal herbicide on spring barley to spraying oilseed rape, potatoes or swedes. Improved formulations of these herbicides are being developed which will reduce the need for complex Fixed jet washing nozzle washout procedures Further information 90 Silsoe Research Institute • Nozzle and sprayer manufacturers • • • • • Pesticide manufacturers AEA AIC AICC CPA Technology links How much will it cost you? Capital cost Small capital cost of retro-fitting systems if they are not already part of the standard equipment on the sprayer £ Operating cost No increase in operating costs - Cost benefits Important benefits, particularly as the disposal of washing water can cost less • Sprayer Control and Maintenance • Sprayer Decontamination 38 Crop Protection section 2 Crop Protection Sprayer Decontamination What is it? Availability and use Sprayer decontamination is the Systems have now been developed effective cleaning of the sprayer and to aid the safe cleaning of sprayers safe disposal of washings. Recent including: from a separate bowser tank. These systems are simple to operate but research has shown that significant contamination of water systems can • pressurised hand lance to wash loading of the sprayer and/or from down the sprayer and spraying cleaning off the internal and external vehicle in an untreated area of surfaces of the application the field where it has been used, machinery. This is especially likely to thus removing the need to occur when filling and cleaning is dispose of washing water. How can it help you? • • The use of a dedicated wash- down area has been prepared by the Environment Agency in England and Wales, and by SEPA in Scotland. Specific filter systems are available to dispose of washings on larger holdings or for use by contractors. Biobeds have been developed in Helps to comply with codes of pressurised clean water for Scandinavia and in the USA, but practice, quality assurance washing. Sprayer washings can their development is still at a requirements and environmental be collected and disposed of relatively early stage in Scotland, regulations at relatively low cost using: England and Wales. The principle is whilst being practical to - a purpose-designated to retain dilute pesticide in a pit treatment system containing a mixture of materials Reduced risk of corrosion on the - a biobed system that will enable the active sprayer giving longer machine life - an approved disposal ingredients to decompose by a contractor process of biodegradation. How can it help the environment? • specification for a sprayer wash- disposal facilities and a supply of and reduced maintenance costs • dilute washings are now available. A down area with appropriate implement • Specifications for sprayer wash-down areas and biobeds for disposing of The use of a clean water result from small spillages during done on a concrete yard area. do increase time in the field. - spraying onto an area of land selected for this purpose Reduced amount of pesticides in Many sprayers can now be fitted the environment with external washing systems as an Reduced risk of groundwater and surface water contamination option. Clean water for washing can be carried on the sprayer or supplied Caution: If you choose to clean the sprayer and the spraying vehicle in the field, leave an area that has not been treated with the full dose of pesticide for washing purposes. Ensure that it is not close to headlands, surface water or a drainage channel. 91 38 Crop Protection section 2 Crop Protection Sprayer Decontamination How much will it cost you? Capital cost Technical tip Different methods of implementation If it is not possible to clean a will have different cost profiles but all machine at the end of a will involve some capital expenditure spraying operation, it should Wash-down system on sprayer for use be stored undercover to in the field £ prevent rain washing surface residues into drains. Construction and maintenance of a dedicated wash-down area and disposal system Operating cost ££ Operating costs are generally low Time to operate in-field cleaning Further information £ Disposal is generally low-cost, except if using processing plant and/or approved contractor Cost benefits Important benefits can be gained from a relatively low-cost system 92 £ • • • • • SEPA ADAS Cherwell Study AEA AIC AICC Technology links • Low Volume Washing Systems • Weed Wipers 39 Crop Protection section 2 Crop Protection Weed Wipers What are they? Availability and use Weed wipers transfer herbicide to a Specialist units are available for target weed by direct contact operation in: that maintains a high level of herbicide at the wick surface but in between the weed and a vehiclemounted boom or hand-lance- • wider units mounted directly on a generally used to exploit the height tractor. • gives the highest herbicide transfer to wiped targets (see figure over). Arable crops – these tend to be mounted wick material. They are difference between target weeds and such a way as to minimise dripping, When transfer rates are high, higher deposits of herbicide are achieved on the upper parts of plants. Some Grassland and areas of value to herbicide is often deposited on lower the base crop or grass sward, wildlife – these tend to be smaller parts of tall plants due to run-off enabling a non-selective herbicide to units suitable for mounting on or from the higher sections. be used and/or reducing overall towing by all terrain vehicles herbicide use. It is important to (ATVs). control wick height and minimise the risk of herbicide dripping from the Such units cannot substitute wick. Skids and wheels are used to completely for a crop sprayer. maintain boom height. How can they help you? • • Chemical transfer by rubbing contact is generally less effective than spraying, particularly in variable Selective control of tall weeds in weed conditions. In areas of high grassland or beet crops with low weed density the wick tends to dry cost herbicides out whereas when the density is low, Reduced quantities of broad dripping can occur. spectrum herbicide used resulting in cost savings • Approaches to improving the performance of weed wipers include: Likely to be an effective way of achieving weed control in environmentally-sensitive grassland, although derogations to use herbicides will still be • in different directions • • • the use of an active contact surface, for example a roller or a required. How can they help the environment? the use of multiple passes often re-circulating rope, that enables the surface of the wick to be kept replenished with chemical • methods of keeping the wick Reduced amount of herbicides in saturated whilst avoiding chemical the environment dripping from the surface; recent No risk of drift to surrounding areas Caution: Care is required to minimise dripping from the wicks and when handling and disposing of used wick materials that have been soaked with herbicide. designs have involved controlled spraying onto the wick or the use of sensors to control herbicide delivery to the wick surface. The use of wipers with a moving surface and with a control system 93 39 Crop Protection section 2 Crop Protection Weed Wipers Deposits from a saturated wick system treating single thistles Technical tip compared with a spray application Operation with selective herbicides is possible 0.04 provided such products have the appropriate registration. 0.035 Plant deposit, ml/g vegetation 0.025 0.02 0.015 0.01 0.005 0 Wiper 94 Wiper Above 150 mm Spray Spray Below 150 mm Silsoe Research Institute – from a study sponsored by Defra 0.03 Relatively few herbicides are approved for application by weed wipers. Ensure the product that you want to use has the correct approval. Further information • • • • • Machinery manufacturers Chemical companies AEA AIC AICC Technology links How much will it cost you? Capital cost Capital cost involved in purchasing a specialised unit Operating cost • ££ Relatively low operating costs associated with wick maintenance. Considerable savings of herbicide when compared with blanket spraying. Cost benefits Some benefits in specific situations £ Sprayer Decontamination 40 Crop Protection section 2 Crop Protection Mechanical Weed Control What is it? Availability and use Mechanical weed control uses Non-selective tine and harrowing cultural control via harrows, brushes machines are commercially or hoes to disrupt weed growth. available, mainly from non-UK Mechanical weed control can be suppliers. Inter-row hoeing systems Inter-row cultivation overcomes the either non-selective or selective. In are also relatively common and at problem of selectivity by cultivating non-selective systems, an overall least one manufacturer in the UK aggressively between the rows, and treatment is applied to the field, now offers a system that uses vision tackling a wide range of weed using light spring tines or brushes, guidance to improve the steering species and growth stages without and control is achieved because the accuracy. This helps to increase both crop damage. The problem is that weeds are more vulnerable to the work rates and the length of time cultivator blades must be accurately tines or brushes than the crop. In over which good performance can be aligned between the crop rows, a selective systems, treatment is maintained without the effects of task that is both difficult and very applied both between and within operator fatigue. tiring using manual methods alone. control and a much reduced risk of crop damage when compared with tine/harrowing treatments applied across the whole crop. Modern vision-based guidance crop rows typically using hoeing blades. Mechanical weed control is Both systems, but particularly the technology now offers a solution to particularly suited to high value non-selective treatments, are very the alignment problem, allowing crops grown with a wide row spacing. dependent upon weather conditions. lateral accuracy within 3cm to be High soil moisture at the time of, achieved at a wide range of speeds. and following treatment can result in Forward speed under most reduced levels of control. Very dry circumstances is limited by the conditions can increase the risk of cultivation operation and may be as crop damage. Scottish weather low as 4km/h in a small sugar beet conditions and soils are less crop or as high as 12km/h in well- favourable for such treatments. established cereals. The work rates Increased soil mineralisation may of inter-row cultivation is limited by lead to increased risk of nitrate the operating width, which is in turn leaching when mechanical determined by drill or planter width. How can it help you? • Provides weed control in a range of conditions without using herbicides • Meets the requirements of organic crop production • No herbicide costs, but several passes may be required How can it help the environment? treatments are used in the autumn. • hoeing (i.e. the selective system) Reduced amount of herbicides in the environment Caution: Timing of treatments is 95 Technological developments Studies have shown that inter-row gives adequate levels of weed associated with computer vision guidance have enabled inter-row hoeing systems to become faster, The control of weeds by inter-row hoeing compared with tine weeding in a randomised plot critical to avoid: • Disruption of ground nesting Treatment Weed dry weight g/m2 g/m2 No weeding 1010 62 Hoe (inter-row) weeding 1230 27 Tine (non-selective) weeding 1150 8 Seek advice from a conservation adviser. • Crop damage and nitrate leaching From Tillett et al., 1999 Crop dry weight, birds and beneficial insects. 40 Crop Protection section 2 Crop Protection Mechanical Weed Control wider and more reliable. Even though this approach is more applicable for Technical tip crops grown in widely spaced rows such as potatoes or vegetables, research has shown it is feasible in widely spaced (e.g. 25cm rows) cereal crops with Timing, weather and soil no substantial loss of yield. conditions are critical to the success of such techniques. A combination of mechanical weeding and minimal rates of low-dose herbicides Take note of weather is being used successfully in Denmark and in the UK in spring barley. forecasts when planning treatments. A guided hoe system Further information 96 Silsoe Research Institute How much will it cost you? Capital cost A significant capital investment in machinery is required for both selective and non-selective approaches. Unless an organic system is being adopted, the machinery for mechanical weed control will be needed in addition to a sprayer Operating cost ££ Higher labour costs than spraying as mechanical treatments have lower work rates. There may be some increased machine maintenance, particularly of soil-engaging parts. However, pesticide costs should be reduced. Cost benefits Offers alternative means where herbicide use must be reduced. Particularly useful in organic production £ • Manufacturers of hoeing and harrowing equipment • • • • • Soil Association AEA AIC AICC SAC Technology links • • Minimum Tillage Appropriate Herbicide Use References Tillett N.D., Hague T., Blair A.M., Jones P.A., Ingle R. and Orson, J.H. (1999). Precision inter-row weeding in winter wheat. Proceedings, The 1999 Brighton Conference – Weeds, 3, 975-980. 41 Harvesting section 2 Harvesting Yield Mapping What is it? Yield mapping produces a contoured field map showing high and low yielding areas of the field. The How can it help the environment? One of the major factors leading to • • Methods for mapping variability in development of satellite based infield location systems such as Global Improved targeting of inputs soils directly using electro-magnetic Reduced amount of pesticides in the environment • variations in yield is soil conditions. induction (EMI) have been developed and good correlation has been Reduced water and atmospheric demonstrated between field areas Positioning Systems (GPS) has pollution by avoiding excess defined from yield maps and from provided a stimulus for the application of fertilisers EMI. The use of soil maps in Aids the identification of areas of conjunction with yield maps can lower productivity that can be increase the value of both maps and used to deliver environmental allow improved interpretation. development of yield mapping systems. The use of a GPS together with a grain flow sensor on the main elevator into the grain tank of a combine harvester and a computer- • benefits, e.g. as set-aside or created habitats based recording system forms the basis of a yield mapping system. Crop responses to different soil conditions in different parts of a field Availability and use will depend on the weather and Recorded data is fed into an analysis program for smoothing/interpolation Most manufacturers of combine underlying soil variability. Because of and plotting as a contour map of harvesters now offer yield mapping this, the interpretation of yield maps crop yield. Yield maps can improve as an optional facility and it is should use data collected over a the management of differing field becoming a standard feature on number of seasons. For example, in areas and help optimise the use of larger machines. Systems can also a dry season, cereal crops on the inputs. be retro-fitted to existing harvesters. heavier parts of a field will tend to How can it help you? Yield maps from a single season can whereas the reverse may be true in provide valuable data relating to a wet season. The analysis of a sequence of yield maps can provide information that will help to: yield higher than on the lighter areas crop performance in that season; however, more information can be obtained by analysing a sequence of • Define different areas of a field that could be managed in different ways so as to optimise the use of inputs and reduce costs • drainage problems • • yield maps collected over a number of cropping seasons. A detailed field assessment of the areas identified from a sequence of yield maps will be necessary to determine appropriate management strategies. Identify compacted areas or soil seasonal effects as well as the The ability to handle large amounts of data within a computer system is Identify areas that could be taken important if the best possible out of primary production information is to be obtained from Provide improved management yield maps. There is currently records relatively little software commercially available that will aid the interpolation of a sequence of yield maps but such approaches are being developed. 97 41 Harvesting section 2 Harvesting Yield Mapping A yield map that can be used to identify areas of a field that can be managed in different ways. 24.5% Technical tip The use of a combine 17.3% operating with a yield 12.3% 11.4% 11.4% driver to follow a defined 7.2% 5.4% 4.5% code of practice so as to 3.6% minimise the time during 4.75-5.00 Over 5.00 4.25-4.75 3.50-4.25 3.25-3.50 3.00-3.25 2.50-3.00 2.25-2.50 1.25-2.25 1.4% up to 1.25 mapping facility requires the which the machine is operating without a full width of cut and avoid Yield (T/ha) misleading anomalies in yield maps. Methods of compensating for variations in cut width are being evaluated but are not yet commercially available Data from SOYL Ltd 98 Note: • • Combine harvester manufacturers • Suppliers of precision farming software packages • • • • AIC Costs are reducing as technology becomes standardised and use of computerised systems becomes more common • Further information The use of infra-red photography from either satellite or aeroplane and chlorophyll-N sensor maps from tractor-mounted sensors can also aid interpretation of yield maps. AICC HGCA SAC How much will it cost you? Technology links Capital cost • • • Electronic Communication • Targeted Phosphate, Potash and Lime Application • Patch Spraying In-field location equipment (e.g. GPS), and grain flow sensor together with recording system ££ Some investment in computer systems in the farm office will be needed if it does not already exist Operating cost £ A small increase in operating costs because of data handling during harvesting, subsequent processing and interpretation Cost benefits High initial capital cost, but once established the system should give useful information at a low cost £ Fertiliser Planning Targeted Nitrogen Application section 2 Making the Most of Technology Making the Most of Technology The products and technologies 6 Fertiliser Planning 7 Nitrogen Diagnostic Technology described in the TIBRE Arable Handbook provide an opportunity for you to improve your farming 13 Manure-Value Diagnostics system, but whether or not they do so in practice will depend on how 14 Improved Manure Storage the individual products or 15 Improved Manure Application Options to help make better use further advice if you need it. It also of inorganic fertilisers: draws your attention to other related system. Generally speaking, environmentally damaging than fungicides. By targeting their use more precisely, you can save money 1 Electronic Communication 2 Internet Information, Prediction impact on the non-farmed areas of Schemes and Tools the farm and in the wider and also reduce the environmental techniques that could be used in This section takes the approach the best starting point for improving insecticides and herbicides are more them and tells you where to go for combination. fungicides or herbicides, targeting the performance of your farming 41 Yield Mapping technologies to get the best out of data sheets on technologies or When you use insecticides, these inputs more effectively may be they are used. Each data sheet gives outline information on how to use Efficient use of insecticides, fungicides and herbicides environment. 6 Fertiliser Planning 7 Nitrogen Diagnostic Technology 8 Targeted Nitrogen Application 9 Targeted Phosphate, Potash and further and describes groups of linked products which will help you to make the most of the technology you adopt. By combining a wider range of products, the overall efficiency of the farming system and Options to help maximise the effectiveness of pest control: Lime Application 1 Electronic Communication 2 Internet Information, Prediction Schemes and Tools the environmental benefits will be maximised. 10 Improved Fertiliser Spreading Characteristics Efficient use of fertilisers and manures 11 Improved Targeting of Fertiliser Close to Field Boundaries If your farm is close to a loch, river or other watercourse which suffers from nutrient enrichment from the 12 Boom Fertiliser Spreaders 41 Yield Mapping surrounding land, you could make most difference by concentrating first on products which can help tackle this and which can also improve your efficiency when using fertilisers and manures. Combining some or all of these options will help ensure that you 3 Variety Choice 4 Novel Seed Treatments 18 Monitoring Pest Activity 19 Decision Support Systems 20 Co-ordinated Slug Control 21 Improved Formulation and Packaging only apply enough fertiliser to satisfy the needs of the crop and that you apply it in a targeted way. This 22 Appropriate Active Ingredient Use 25 Appropriate Insecticide use ensures that less is wasted by losing Options to help make better use of slurries and manures: 1 Electronic Communication 2 Internet Information, Prediction it from the field into the wider damage to hedgerows, ponds and other non-farmed areas. Schemes and Tools 26 Pesticides Mixtures environment and that there is less 41 Yield Mapping 99 section 2 Making the Most of Technology Making the Most of Technology Options to help maximise the Spraying equipment which can effectiveness of disease control: be used to help with the control of pests, weeds and diseases: 1 Electronic Communication 2 Internet Information, Prediction 27 Pesticide Handling Systems Schemes and Tools 28 Sprayer Control and Maintenance 3 Variety Choice 4 Novel Seed Treatments 29 Patch Spraying 30 Appropriate Spray Quality 17 Crop Diagnostics 31 Drift Reduction by Nozzle 19 Decision Support Systems 21 Improved Formulation and Selection 32 Air Assisted Spraying Packaging 33 Air Induction Nozzles 22 Appropriate Active Ingredient Use 34 Twin Fluid Nozzles 24 Appropriate Fungicide use 35 Rotary Atomisers 26 Pesticides Mixtures 36 Low Volume Spraying 41 Yield Mapping 37 Low Volume Washing Systems 100 Options to help maximise the 38 Sprayer Decontamination effectiveness of weed control: 1 Electronic Communication 2 Internet Information, Prediction Schemes and Tools 19 Decision Support Systems 21 Improved Formulation and Efficient management of soil and water resources 1 Electronic Communication 2 Internet Information, Prediction Schemes and Tools Packaging 22 Appropriate Active Ingredient Use 23 Appropriate Herbicide use 26 Pesticides Mixtures 39 Weed Wipers 40 Mechanical Weed Control 41 Yield Mapping 5 Minimum Tillage (soil) 16 Precision Irrigation (water) 41 Yield Mapping section 3 Supplementary Information Products Under Development The options described in the TIBRE Arable Handbook provide a snapshot of some of the tools available to farmers and their advisers. Legislation as well as pressures from consumers, food retailers and distributors will ensure that industry • the electronic labelling of chemical inputs • the automatic transfer of information from mobile machinery and field sensors to the farm office and adviser and research organisations will Developments in molecular biology and ecology are now being integrated with long term benefits for agronomy and crop improvement. Genomics involves the large-scale use of molecular techniques for identification and functional analysis of complete or continue to refine these products The continued development of lower- nearly complete genomic and to develop new technologies. dose, more specifically-targeted complements of genes. Crop pesticides will reduce the improvements using the tools of Several new technologies are environmental load in key areas, genomics will have a significant developing rapidly at present, but such as control of grass weeds, impact on ways in which crops not all have been included in this where current options are of concern respond and interact with their biotic updated edition of the TIBRE Arable due to links to water pollution. and abiotic environment. For Handbook either because they are Higher specificity of action of example, modifying weed-crop too far from the market or because insecticides will reduce impacts on interactions in favour of the crop will their environmental advantages are beneficial insects. improve yields and quality while not yet clear. reducing weed problems. The use of plants and bacteria to It is likely that relevant technologies bioremediate washout facilities or Progress in crop modelling has been will continue to develop rapidly, other contaminated areas will reduce matched with advances in crop particularly where there are strong pollution risk and lower physiology, crop ecology and drivers for applications in other environmental load. The use of computing technology. Crop models industries as well as in agriculture. specific fungi which attack certain have the potential to facilitate The main areas that are likely to see weeds or fungal pathogens in the decision making by allowing farmers significant developments in the next soil, for example Sclerotinia, will and agronomists to broaden their five to ten years include: develop and be implemented management skills to address issues particularly for high value crops or of environmental and ecological the continued development of where chemical alternatives are not aspects of crop production. This is lower-dose and more specifically- available. essential for realisation of other • targeted pesticides • the development and implementation of decision support systems • • improvements in plant performance. developed to collect soil information The development of in-field sensors Reflectance of the soil relates to and plant diagnostics linked into corresponding nutrient contents (e.g. decision support systems and the P, K, Ca, and Mg) along with pH and use of GPS precision applications will the development of soil nutrient soil organic matter content. This allow more detailed part-field sensors could be useful in the development solutions to problems and improved developments in molecular of a soil nutrient sensor for site- targeting of specific pests in the field biology and ecology specific crop management. This will and in store. decontamination • on the environment or some way off, prototypes are being to assist in fertiliser rate evaluation. the use of plants and bacteria for bioremediation and • benefits in sensing and monitoring Although soil nutrient sensors are development of on-farm diagnostics and in-field sensors linked to decision support systems help to maximise efficiency of inputs and reduce nutrients run off and leaching 101 section section 30 Variety Choice -1 Supplementary Information Products Under Development 102 Automated product labelling is well Important developments are also particularly level of machine use, established in all parts of the retail likely in the handling of information associated with different parts of a sector and is mainly based on bar on arable farms. Sophisticated field. This could be provided by codes. However, such printed codes equipment on field machinery, such recording systems which are are unlikely to be sufficiently robust as that used for the collection of currently under development. This for reliable operation in physically data for yield mapping, is now well information, together with hostile agricultural environments – established. However, the data information from yield maps, will for example, wet or dusty transfer from machine to the farm enable management decisions about conditions. On the other hand, the office normally involves manually cropping plans to be made in a way development of the electronic tag doing this using a device such as a that maximises both financial return (Radio Frequency Identification ‘smart card’. The development of and environmental benefit. Device - RFID) gives important automated data transfer systems, capabilities that can help with record for example based on mobile keeping and traceability in the telephone technology, will enable agricultural industry. The field machinery to communicate development of such tags for use in automatically with the farm office situations such as retail outlets and with the minimum need for manual luggage handling facilities at airports intervention. Associated gives advantages of low volume and developments are likely to: hence a low unit cost. The use of electronic labels on pesticide and • improve the compatibility of fertiliser packaging will provide field different components within the equipment with information on the farming system, particularly in the material being applied. This will area of electronic communication enable: • • simplify the interface with the the automatic generation of users so that operation of both application records – operation hardware and software is less with control systems using field complex location equipment such as GPS will enable detailed records of inputs at both the field scale and within individual fields There should also be further developments in the use of sensing systems and the ways in which the outputs from sensors can be • the more precise control of interpreted. Systems using more application machinery to improve than one method of sensing are targeting of inputs based on both likely to be developed for monitoring the target and the material to be factors such as crop condition. applied Developments in the financial • automatic inventory control for support systems for arable on-farm stores, particularly since agriculture may mean that it is tags can be both read and have important for farmers to have data written to them information on the inputs, section 3 Supplementary Information Good Management Practices The importance of arable land that nesting birds are left In order to maximise the wildlife for wildlife undisturbed. benefit, position field margins Allow nesting birds about eight alongside hedgerows or valuable for wildlife, with many weeks to hatch between first and watercourses where they act as a species of plants and birds relying second rollings. buffer strip helping to protect Arable land can be extremely purely on cultivated farmland. Spring sown cereals provide short vegetation suitable for nesting lapwing and skylark, with winter • • If possible do not plough stubbles watercourses and boundary habitats. in until the end of February. • Different types of field margins Plan crop rotations carefully to restore soil fertility and reduce stubbles providing an important the need for pesticides. source of spilt grain and weed seeds • include tussocky grass strips, grass and wildflower strips. Grass strips across the middle of fields are called Try to ensure that a variety of Beetle Banks and are especially corn bunting and linnet. Arable crops are growing at the same suitable in bigger fields as a way of farms are also important for time to create different habitats providing areas for wildlife in a mammals such as brown hare, for a for wildlife, as this will help cultivated landscape. range of insects and for important provide food and shelter rare arable plants. Most of the TIBRE throughout the year. for birds such as grey partridge, Boundary features Hedges, ditches and dykes are Arable Handbook provides advice on in-field measures that can be taken Field margins important features in the landscape, to minimise any adverse The careful management of field contributing especially to the scenic environmental impacts by using margins will be one of the most value of an area. They provide a modern technology. This section important ways to increase the habitat for all kinds of wildlife looks at management of the rest of diversity of plants and wildlife on an including beneficial insects such as an arable unit that can be done to arable farm. Field margins are often butterflies and ladybirds, and benefit biodiversity. the least productive area of a field mammals such as bats and and many benefits for wildlife can be hedgehogs, and are a prime source Priority species of arable achieved with just a one-metre grass of food, shelter and cover for hedge- farmland require the most strip between the field boundary and nesting species and farmland birds. urgent conservation action. the crop edge. They can benefit In general, the thicker the hedge, Species such as grey small mammals such as mice and the more wildlife benefit it provides. partridge, corn bunting, barn voles, providing ideal hunting areas Trees in hedge lines are also owl, yellowhammer, linnet, for barn owls and kestrels. They can important for the landscape and help bullfinch, pipistrelle bat, also help to reduce the impact of to increase bird numbers. A good brown hare and cornflower fertiliser and pesticide on sensitive mix of species in hedges provides are characteristic of arable habitats nearby and can help comply seeds and berries throughout the farmland, but their numbers with LERAP requirements. winter, which is one of the main reasons why hedge trimming should have decreased over the last two decades or so. As well as giving wildlife benefits, not be carried out every year. grass margins help reduce the Good management spread of hedgerow weeds into the Conservation Headlands There are many actions that can be crop and encourage predatory A conservation headland is a less taken to encourage wildlife on insects that can help to control crop intensively managed strip at the cropped land: pests. They are inexpensive, easy to outer edge of the crop – with less • Minimise the time between establish and require very little fertiliser and pesticide applied than harrowing, sowing and rolling so maintenance. elsewhere in the field. Conservation 103 section 3 Supplementary Information Good Management Practices • headlands are a key habitat because for two years. It can also be sown of the broad-leaved weeds that grow on set-aside and is a good way of that provides food and shelter for in them and the insects that they making use of these areas to benefit gamebirds as well as other support. Insects in turn are food for wildlife. wildlife. Take up the wild bird cover option gamebird chicks and other birds. The weeds provide seeds for small Set-aside mammals and the flowers nectar for The way set-aside is managed has a butterflies. This less dense part of significant impact on its wildlife the crop provides an area of easily value. If managed to benefit used cover for young birds. conservation, set-aside can provide Conservation headlands are also a seeds and cover for wildlife, refuge for rare and declining plants particularly over winter. Set-aside and many species of beneficial management options include natural insects. By tilting the spreader or regeneration, wildlife cover and switching off the outer section of the wildflower mixes. In order to sprayer to reduce fertiliser and maximise the environmental benefit, pesticide inputs in the outer six- you can: metre strip, these environmental • benefits can be achieved. 104 Alter the cutting and spraying dates to benefit grey partridge, lapwing, skylark and brown hare. Wild Bird Cover • Grant Aid Much of the wildlife management above is eligible for support under agri-environment schemes (such as the Rural Stewardship Scheme) or from other local funding sources. Contact your local SEERAD office for details of agri-environment schemes available or seek advice from conservation advisers at FWAG or SAC. Further information Further detailed information on all these management options is Delay cutting as late as possible, available from organisations such as Wild bird cover (or unharvested and consider leaving up to 20% FWAG, RSPB and SAC Conservation crops) is an important way of uncut in any one field for up to Services. increasing wildlife areas on a farm; three years. by acting as a giant bird table, it provides a source of insects and • around field margins for up to seeds throughout the year to benefit birds such as grey partridge and yellowhammer and mammals such as brown hares and bats. Wild bird cover should contain a mix of at least two crop types such as a cereal and a brassica and is usually down Leave up to two metres uncut three years. • Locate set-aside along hedgerows, field margins, dykes and ditches to buffer these areas from farming activities. section 4 Appendices Sources of Further Information ADAS AICC in Scotland: Crop Protection Association Registered Office: ADAS Holdings Contact Allathan Associates (CPA) Limited Hallhill 4 Lincoln Court Woodthorne Turriff AB53 4BL Lincoln Road Wergs Road Tel: 01888 563464 Peterborough PE1 2RP Wolverhampton WV6 8TQ Fax: 01888 563951 Tel: 01733 349225 Tel: 01902 754190 Email: Fax: 01733 562523 Fax: 01902 743602 allathan.associates@farmline.com Email: info@cropprotection.org.uk Email: enquiries@adas.co.uk http://www.adas.co.uk/ http://www.cropprotection.org.uk/ BASIS (Registration) Ltd 34 St John Street CSC CropCare & CSC PotatoCare Agricultural Engineers’ Ashbourne DE6 1GH CSC Crop Protection Ltd. Association (AEA) Tel: 01335 343945 Glenearn Road Samuelson House Fax: 01335 346488 Perth PH2 0NL Paxton Road http://www.basis-reg.com Tel: 01738 623201 Orton Centre Fax: 01738 630360 Peterborough PE2 5LT British Potato Council (BPC) Tel: 01733 362925 Scottish Office Fax: 01733 370664 Rural Centre Central Science Laboratory (CSL) Email: tech@aea.uk.com West Mains Sand Hutton http://www.aea.uk.com/ Newbridge EH28 8NZ York YO41 1LZ http://www.csccrop.co.uk/cropcare/ Tel: 01314 724064 Tel: 01904 462000 Agricultural Industries Fax: 01314 724065 Fax: 01904 462111 Confederation (AIC) http://www.potato.org.uk/ Email: science@csl.gov.uk Confederation House http://www.csl.gov.uk/ East of England Showground The British Beekeepers Peterborough PE2 6XE Association FACTS Tel: 01733 385230 The National Beekeeping Centre Contact BASIS Fax: 01733 385270 National Agricultural Centre Email: enquiries@agindustries.org.uk Stoneleigh Park CV8 2LG Farming and Wildlife Advisory http://www.agindustries.org.uk/ Tel: 02476 696679 Group (FWAG) http://www.bbka.org.uk/ Scottish Head Office Algo Business Centre Association of Independent Crop Consultants (AICC) British Society of Plant Breeders Glenearn Road Head Office: Agriculture House (BSPB) Perth PH2 ONJ Station Road Woolpack Chambers Tel: 01738 450500 Liss GU33 7AR 16 Market Street Fax: 01738 450495 Tel: 01730 895354 Ely CB7 4ND http://www.fwag.org.uk/scotland/ Fax: 01730 895535 Tel: 01353 653200 Email: aicc@farmline.com Fax: 01353 661156 http://www.aicc.org.uk/ Email: enquiries@bspb.co.uk http://www.bspb.co.uk/ 105 section 4 Appendices Sources of Further Information Home Grown Cereals Authority Pesticides Safety Directorate Scottish Crop Research Institute (HGCA) (PSD) (SCRI) Caledonia House Mallard House Invergowrie 223 Pentonville Road Kings Pool Dundee DD2 5DA London N1 9HY 3 Peasholme Green Tel: 01382 562731 Publications York YO1 7PX Fax: 01382 562426 Email: publications@hgca.com Tel: 01904 455775 http://www.scri.sari.ac.uk/ Tel: 020 7520 3920; Fax: 01904 455733 Fax: 020 7520 3958 Email: Scottish Executive Environment Research & Development information@psd.defra.gsi.gov.uk Rural Affairs Department Email: research@hgca.com http://www.pesticides.gov.uk/ (SEERAD) Tel: 020 7520 3945; Contact your local SEERAD Area Fax: 020 7520 3992 Rothamsted Research http://www.hgca.com/ Harpenden AL5 2JQ Tel: 01582 763133 Head Office: Linking Environment and Fax: 01582 760981 Pentland House Farming http://www.rothamsted.bbsrc.ac.uk/ 47 Robb’s Loan Edinburgh EH14 1TY (LEAF) 106 Office The National Agricultural Centre Royal Society for the Protection Tel: 0131 5568400 or 0845 7741741 Stoneleigh of Birds (RSPB) http://www.scotland.gov.uk/agri Warwickshire CV8 2LZ RSPB Scotland Tel: 02476 413911 Dunedin House Scottish Environment Protection Fax: 02476 413636 25 Ravelston Terrace Agency (SEPA) E-mail: enquiries@leafuk.org Edinburgh EH4 3TP Contact your local SEPA office http://www.leafuk.org/ Tel: 0131 3116500 National Sprayer Testing Scheme Email: rspb.scotland@rspb.org.uk Head Office: http://www.rspb.org.uk/scotland/ Erskine Court Castle Business Park (NSTS) Samuelson House Scottish Agricultural College STIRLING FK9 4TR Paxton Road (SAC) Tel: 01786 457700 Orton Centre West Mains Road Fax: 01786 446885 Peterborough PE2 5LT Edinburgh EH9 3JG http://www.sepa.org.uk/ Tel: 01733 362925 Tel: 0131 5354185 Fax: 01733 370664 Fax: 0131 5354332 Silsoe Research Institute Email: info@nsts.org.uk Email: information@ed.sac.ac.uk Wrest Park http://www.aea.uk.com/sprayer/ http://www.sac.ac.uk/ Silsoe Processors and Growers Scottish Agricultural Science Tel: 01525 860000 Research Organisation (PGRO) Agency (SASA) Fax: 01525 860156 The Research Station East Craigs Email: sri.pr@bbsrc.ac.uk Great North Road 82 Craigs Road http://www.sri.bbsrc.ac.uk/ Thornhaugh Edinburgh EH12 8NJ Peterborough PE8 6HJ Tel: 0131 2448890 Tel: 01780 782585 Fax: 0131 2448940 Fax: 01780 783993 Email: info@sasa.gsi.gov.uk http://www.pgro.co.uk/ http://www.sasa.gov.uk/ Bedford MK45 4HS section 4 Appendices Sources of Further Information Soil Association To see a demonstration of the TSO Customer Services Bristol House Environmental Management for PO Box 29 40-56 Victoria Street Agriculture (EMA) software St Crispins House Bristol BS1 6BY package and purchase a copy, Duke Street Tel: 01179 290661 visit: Norwich NR3 1GN Fax: 01179 252504 http://www.herts.ac.uk/aeru/ema/ Tel: 0870 600 5522 Email: info@soilassociation.org EMA help line: Fax: 0870 600 5533 http://www.soilassociation.org/ Email: ema@herts.ac.uk http://www.tso.co.uk/ Tel: 01707 284548 Soil Management Initiative Fax: 01707 284185 UK Soil Management Initiative Ltd British Standards 6356 can be obtained from the TSO bookshop. 1, The Paddocks For the Scottish Executive Powey Lane publications, contact: For information on the UK Mollington Scottish Executive Desk Pesticide Guide and how to Chester CH1 6LH The Stationery Office Bookshop order, visit Email: smi@smi.org.uk 71 Lothian Road http://www.ukpesticideguide.co.uk/ http://www.smi.org.uk/ Edinburgh EH3 9AZ Tel: 0870 606 5566 The Precision Farming Alliance http://www.scotland.gov.uk/publicati Email: p.f.alliance@bbsrc.ac.uk ons/ Voluntary Initiative Or contact your local SEERAD Area Email: info@voluntaryinitiative.org.uk Office (For technical enquiries about crop protection management plans, email For Defra (and MAFF) cpmp@voluntaryinitiative.org.uk) publications, contact: http://www.voluntaryinitiative.org.uk/ Defra Publications Admail 6000 Environmental Information Sheets London SW1A 2XX can be found on the Voluntary Tel: 08459 556000 Initiative web site. Fax: 020 8957 5012 Email: defra@iforcegroup.com The Fungicide, Insecticide and http://www.defra.gov.uk/corporate/p Weed Resistance Action Groups ublications guidelines can be found on the PSD web site http://www.pesticides.gov.uk/rags_ho me.asp 107 section 4 108 Appendices section 4 Appendices Acronyms AEA: Agricultural Engineers’ Association AIC: Agricultural Industries Confederation AICC: Association of Independent Crop Consultants BPC: British Potato Council BSPB: British Society of Plant Breeders CPA: Crop Protection Association CSL: Central Science Laboratory CUPGRA: Cambridge University Potato Growers Research Association Defra: Department for Environment Food and Rural Affairs DSS: Decision Support Systems EIS: Environmental Information Sheets EMA: Environmental Management for Agriculture EMI: Electro-Magnetic Induction FWAG: Farming and Wildlife Advisory Group GPS: Global Positioning Systems HGCA: Home Grown Cereals Authority LEAF: Linking Environment and Farming LERAP: Local Environment Risk Assessment for Pesticides NFUS: National Farmers’ Union Scotland NPTC: National Proficiency Tests Council NSTS: National Sprayer Testing Scheme PGRO: Processors and Growers Research Organisation PCR: Polymerase Chain Reaction PSD: Pesticides Safety Directorate RSPB: Royal Society for the Protection of Birds SAC: Scottish Agricultural College 109 section 4 Appendices Acronyms 110 SASA: Scottish Agricultural Science Agency SCRI: Scottish Crop Research Institute SEERAD: Scottish Executive Environment Rural Affairs Department SEPA: Scottish Environment Protection Agency SRI: Silsoe Research Institute VI: Voluntary Initiative 52105_Inner_Cover 13/1/05 8:47 am Page 1 Scottish Natural Heritage is a government body responsible to the Scottish Executive Ministers, and through them to the Scottish Parliament. Our mission statement: Working with Scotland’s people to care for our natural heritage. Our aim: Scotland’s natural heritage is a local, national and global asset. We promote its care and improvement, its responsible enjoyment, its greater understanding and appreciation and its sustainable use now and for future generations. TIBRE Arable Handbook Our operating principles: We work in partnership, by co-operation, negotiation and consensus, where possible, with all relevant interests in Scotland: public, private and voluntary organisations, and individuals. We operate in a devolved manner, delegating decision-making to the local level within the organisation to encourage and assist SNH to be accessible, sensitive and responsive to local needs and circumstances. We operate in an open and accountable manner in all our activities. TIBRE Arable Handbook Further copies of this book are available from Scottish Natural Heritage Publications Section Battleby Redgorton Perth PH1 3EW t: 01738 444177 f: 01738 458613 e: pubs@snh.gov.uk w: www.snh.org.uk Copyright Scottish Natural Heritage 2004 ISBN 1 85397 416 1 TP1.5K1204