Effects of different organic fertilizers on seedlings growth and

Transcription

Effects of different organic fertilizers on seedlings growth and
ORIGINAL SCIENTIFIC PAPER
Effects of different organic fertilizers on
seedlings growth and photosynthesis of chinese
cabbage (Brassica rapa ssp. pekinensis)
Mohamed A. SHARAF-ELDIN1, Katalin ERTSEYNÉ PEREGI2, Zoltan PAP2
Kafrelsheikh University, Faculty of Agriculture, Department of Horticulture, Egypt
Corvinus University of Budapest, Faculty of Horticultural Science, Department of Vegetable and Mushroom Growing, Hungary,
(e-mail: zoltan.pap3@uni-corvinus.hu)
1
2
Abstract
While the nutrient supply in conventional farming is mainly provided by mineral fertilizers,
organic farmers have to use organic materials to produce seedlings for increasing growth and
quality. Although the effect of pelleted and granulated composted animal manures is known
in organic production, till this time there is no scientific literature in Hungarian and Egyptian
situations to use them for organic seedling production. Aims of research were to determine
growing power of Chinese cabbage seedlings only with the use of organic materials (pelleted
or microgranulated added to peat), estimating the effectiveness of different NPK values (4-4-4
or 10-3-3), and to demonstrate some physiological differences by measuring photosynthetic
activity. All organic fertilizers increased seedlings fresh and dry weights, nitrogen and
chlorophyll contents and photosynthetic rate. However, microgranulated organic fertilizer
(NPK: 4-4-4) was the most effective.
Key words: Chinese cabbage, seedlings, transplant growth, photosynthesis, pelleted organic
fertilizer
Introduction
Transplant production is a specialized segment of the vegetable business that demands suitable facilities and
careful attention to detail. For these reasons, many vegetable growers choose to purchase transplants from
production specialists (Maynard and Hochmuth, 2007) because of quality of yield (Montemurro and Maioranna,
2009), however it is elaborated better in conventional farming. The primary components of growing media for
vegetable transplant production are peat moss, perlite, and vermiculite. Some study pointed to peat is a slowly
renewable material with diminishing availability (Raviv et al., 1998), however one of the most useful content
of organic media. Moreover organic seedling production is needed to suit to two principles: first, the growing
substrates have to fit the organic farming disciple (use of chemicals e.g. fertilizers, strong germ-killers, herbicides
are forbidden), second, only allowed materials and biological agents (like natural predators, parasites) can be
used in organic plant protection. The traditional way to raise a lot of seedlings is to sprout seeds in trays, then
transplant these fragile plants into larger packs or pots. This method is very labour-intensive and results in
considerable mortality from transplant shock or root loss (Lane Greere, 2005). Developing transplants need
fertilization as well with nitrogen, phosphorus, and potassium to develop stocky, vigorous transplant, ready to
the field. Many commercial soilless transplant mixes have a starter nutrient charge (Maynard and Hochmuth,
2007). While plant nutrition is well solved in conventional technologies with use of synthetic fertilizers till
then there are several unsolved questions in organic production. However, the development of high-quality
compost from organic wastes must be focused on specific agricultural activities in order to justify the associated
production cost of compost and also to obtain the compost quality demanded by each user (Moral et al., 2009).
The effect of chemical fertilizers can be faster in some cases, but the organic fertilizers are mostly more effective
and the influence is also longer (Saleh et al., 2010). In addition, land application of manures allows reuse and
recycling of the waste, and that can be a useful practice where farmers have a surplus of poultry manure (Singh
et al., 2014). It is well-known long time ago that in average of given macro-elements, phosphorus is one of
Proceedings . 50th Croatian and 10th International Symposium on Agriculture . Opatija . Croatia (286–290)
286
50th Croatian and 10th International Symposium on Agriculture
Effects of different organic fertilizers on seedlings growth and photosynthesis of chinese cabbage (Brassica
rapa ssp. pekinensis)
the most important for adequate root development moreover mobilization of nutrients can be operated by
microorganisms especially by VAM fungi (Rhodes and Gerdemann, 1978). However for greenery of transplant
is also necessary to calculate with large amount of nitrogen that have affect for chlorophyll synthesis (Pap et
al., 2013), and it can be possible to measure with rational methods (Blackmer and Schepers, 1995). The aim
of our research is to analyse the nutriment supplier ability of some animal manure composts. They include
different values of macro elements, use in compound with Baltic peat and to examine the influence of these for
Chinese cabbage (Brassica rapa L. var. pekinensis [LOUR]. Olsson) seedling development, nutrient uptake, and
coherence of them with photosynthetic activity, chlorophyll synthesis and stomatal conductivity.
Material and methods
The experiment was set in the greenhouse of the Central Arboretum of Buda of the Corvinus University of
Budapest, Faculty of Horticultural Science, Department of Vegetable and Mushroom Growing, between 20th
of April, 2014 and 15th of May, 2014.
Used materials: Seeds of Chinese cabbage ‘Gigant’ variety; KITE polystyrene tray for transplant growing,
number of cells: 60; Perlite (Perlite Pannonia Ltd.) – horticultural perlite with 0-6 mm particle size for covering;
Kekkilä Peat (nature peat for seedlings) – pH: 6.5-7; Organic fertilizer from chicken manure in pelleted and
in micro-granulated form. This material contains high level of nitrogen, phosphorus and potassium (4-4-4),
and amino acids, humic, and fulvol acid compounds (WEB 1); Organic fertilizer with increased nitrogen
level (WEB 2). As shown in Table 1, 4 treatments were tested in the experiment. The experiment was set
up according to the trial scheme with 3 repetitions (1 repetition meant 30 pieces of Chinese cabbage plant).
During the growing data collector measured the temperature and air humidity every 30 minutes, the measured
environmental conditions are traceable in Figure 1.
Table 1. Treatments and marking during experiment (2014)
Treatment 1
Control – peat only, without any fertilizer – 3 trays
Treatment 2
Peat + Pelleted organic fertilizer (NPK: 4-4-4) cc: 1 v/v % – 3 trays
Treatment 3
Peat + Microgranulated organic fertilizer (NPK: 4-4-4) cc: 1 v/v % – 3 trays
Treatment 4
Peat + Pelleted organic fertilizer (NPK: 10-3-3) cc: 0,75 v/v % – 3 trays
Measurements and analytical methods
The following parameters were determined in random 10 plants from each treatment:
• Dry matter content of shoots and roots (calculated from fresh and dry weights)
• Plant length (till top of longest leaf) and diameter (1 cm above media surface)
• Photosynthetic rate (with use of LCi Portable Photosynthesis System measurer – ADC BioScientific Ltd.)
• Chlorophyll content with use of Konica-Minolta SPAD 502 Chlorophyll meter
• Nitrogen values in leaf and root with use of Kjeldahl method (Sáez-Plaza et al, 2013)
• Valuation with Microsoft Office Excel 2013, and IBM SPSS 22 statistical software.
Section 4 . Vegetable Growing, Ornamental, Aromatic and Medicinal Plants
287
Mohamed A. SHARAF-ELDIN, Katalin ERTSEYNÉ PEREGI, Zoltan PAP
Figure 1 Measured daily average temperature and humidity in glasshouse
Results and discussion
In this experiment all of chicken manure treated transplants were more developed than the non-treated ones.
Germination ratio was above 90% in every tray with no any significant difference, it can prove calculation of
used fertilizer didn’t reach inhibitor effect. In Table 2 the measured and calculated physical status is observable
of transplants. Most of the cases significant differences are not traceable however where it is perceptible there
was visible on living plants as well. In Table 3 a sample Post Hoc test of ANOVA is prove that the control
definitely differ from treated plants, and treatment 3 stands in weak significant coherence with treatment 2
(with value of 0.465). In test the significant values are higher where correspondence is verifiable. In our results
control was significantly differing, and treatment 3 was similar with lower significant value.
Table 2 Measured and calculated values of seedling physical status at the end of growing (with standard
deviation)
Transplant (mm)
Treatment
Fresh weight (g)
Dry weight (g)
Dry matter (%)
Diameter
Length
Shoots
Roots
Shoots
Roots
Shoots
Roots
Roots/
shoots
1
2.32
±0.36
148.7
±1.43
2.88
±0.65
0.35
±0.15
0.22
±0.04
0.03
±0.05
8.26
±0.57
7.52
±0.18
0.91
±0.07
2
2.28
±0.48
205.8
±1.69
6.26
±1.92
0.38
±0.18
0.35
±0.55
0.03
±0.09
9.50
±3.22
5.60
±0.07
0.64
±0.20
3
2.13
±0.26
198.8
±2.11
6.34
±1.80
0.52
±0.33
0.38
±0.23
0.04
±0.06
8.42
±1.48
6.05
±0.24
0.73
±0.11
4
2.15
±0.32
202.8
±2.11
6.51
±2.17
0.41
±0.21
0.35
±0.05
0.03
±0.02
6.68
±1.79
5.43
±0.11
0.85
±1.79
However it was measurable in weight of fresh roots and shoots and microgranulated organic fertilizer (NPK:
4-4-4) achieved higher values (treatment 3). In dry material we can observe an inverse ratio that proves
Kappel’s (2006) statements, that lower dry material content is traceable beside optimal, or higher water and
nutrient uptake. According to Figure 2, our measured Kjeldahl nitrogen, and SPAD values are in relationship,
which can verify statements of Chang and Robinson (2003). Microgranulated organic fertilizer (NPK: 4-4-4)
attained higher nitrogen and chlorophyll (SPAD) contents of the seedlings, while the control was the lowest.
It was also noticed that all organic fertilizers increased photosynthetic rate compared to the control. In Figure
3, it can be observable a massive difference between control and treated groups. In case of control the values
of photosynthetic rate was lower and it is supposedly the succeeding of the SPAD results. Plants have more
intensive photosynthetic activity with higher amount of chlorophyll content which was measured by rapid and
non-destructive method (Yadava, 1986). Our measurements are validate results of Bayoumi et al. (2008), where
the used composts (for element of media) with higher nitrogen and phosphorus content gave significantly
more developed tomato transplants with higher SPAD values.
288
50th Croatian and 10th International Symposium on Agriculture
Effects of different organic fertilizers on seedlings growth and photosynthesis of chinese cabbage (Brassica
rapa ssp. pekinensis)
Table 3 ANOVA test – Multiple comparisons on length of transplants with Games-Howel test
Treatments
1
2
3
4
Mean Difference (I-J)
Standard Error
Significance
2
-5.71667
*
.40401
.000
3
-5.01667
*
.46462
4
-5.42000*
.46543
1
5.71667
*
3
.70000
95% Confidence Interval
Lower Bound
Upper Bound
-6.7862
-4.6471
.000
-6.2507
-3.7827
.000
-6.6562
-4.1838
.40401
.000
4.6471
6.7862
.49350
.493
-.6072
2.0072
4
.29667
.49426
.932
-1.0125
1.6059
1
5.01667*
.46462
.000
3.7827
6.2507
2
-.70000
.49350
.493
-2.0072
.6072
4
-.40333
.54492
.880
-1.8447
1.0380
1
5.42000*
.46543
.000
4.1838
6.6562
2
-.29667
.49426
.932
-1.6059
1.0125
3
.40333
.54492
.880
-1.0380
1.8447
*The mean difference is significant at the 0.05 level
Figure 2 Differences of
measured average SPAD
and nitrogen values on
treatments
Figure 3 Photosynthetic
rates of leaves on Chinese
cabbage
Interestingly, the SPAD chlorophyll content was lower in treatment 4 (peat + organic fertilizer with increased
nitrogen) compared to treatment 3 (equilibrium NPK, 4-4-4), but there was found the highest value of measured
photosynthetic rate. Photosynthetic rate and SPAD values of chlorophyll content was in weak correlation,
however different groups of our treatments (with or without manure) can be traceable. In brief conclusion,
substrates mixed with organic fertilizer can generate bigger greenery, higher amount of chlorophyll content,
better nutrient and water up-take, and it should have an effect to increase photosynthetic activity of transplants
as well.
This paper is supported by the ‘Postdoc Scholarship Program’ of ÖMKI, Hungary.
Section 4 . Vegetable Growing, Ornamental, Aromatic and Medicinal Plants
289
Mohamed A. SHARAF-ELDIN, Katalin ERTSEYNÉ PEREGI, Zoltan PAP
References
Bayoumi, Y.A., El-Mahrouk, M.E., El-Aidy, F., Pap, Z. (2008). Using composts of grape
manufacture and farm wastes as growing media in vegetable and ornamental nurseries.
International Journal of Horticultural Science 14(3):45-50
Blackmer, T.M.; Schepers, J.S. (1995). Use of a chlorophyll meter to monitor nitrogen status
and schedule fertigation for corn. Journal of Production Agriculture 8(1):56-60
Chang, X.S., Robison, D.J. (2003). Nondestructive and rapid estimation of hardwood foliar
nitrogen status using the SPAD-502 chloroohyll meter. Forest Ecology and Management
181:331-338
Greer, L. (2005). Plug and Transplant Production for Organic Systems. NCAT Agriculture
Specialist (www.attra.ncat.org/attra-pub/PDF/plugs.pdf)
Kappel N. (2006). Major physical properties of soil mixes for growing vegetable seedlings.
Peer review of Zöldségpalánták nevelésére alkalmas földkeverékek legfontosabb fizikai
tulajdonságai. Doktori értekezés (PhD dissertation), Corvinus University of Budapest, Dep.
of Vegetable and Mushroom Growing, Budapest, Hungary, 49
Maynard, D.N., Hochmuth, G.J. (2007). Knott’s Handbook for Vegetable Growers. John Wiley
& Sons, Inc. New Jersey, USA, 55-103
Montemurro, F., Maiorana, M. (2009). Organic fertilization as resource for a sustainable
agriculture. In: Elsworth, L.R., Paley, W.O. (editors): Fertilizers – Properties, Applications
and Effects. Nova Science Publishers, Inc., New York, USA, 123-147
Moral, R., Paredes, C., Bustamante, M.A., Marhuenda-Egea, F., Bernal, M.P. (2009). Utilisation
of manure composts by high-value crops: Safety and environmental challenges. Bioresource
Technology 100(22):5454-5460
Pap, Z., Király, Á., Kis Krisztiánné, B.M. (2013). Effect of azotobacter products on lettuce
transplants. Agriculture and Rural Development: New Challenges from 2014. – XII.
Wellmann International Scientific Conference, Hódmezővásárhely, Hungary
Raviv, M., Zaidman, B.-Z., Kapulnik, Y. (1998). The use of compost as a peat substitute for
organic vegetable transplants production. Compost. Sci. Utiliz. 6(1):46-52
Rhodes, L.H., Gerdemann, J.W. (1978). Influence of phosphorus nutrition on sulfur uptake by
vesicular-arbuscular mycorrhizae of onion. Soil Biol. and Biochem. 10(5):361-364
Saleh, S.A., Glala, A.A., Ezzo, M.I., Ghoname, A.A. (2010). An attempt for reducing mineral
fertilization in lettuce production by using bio-organic farming system. Acta Horticulturae
852:311-318
Sáez-Plaza, P., Michalowski, T., Navas, M.J., Asuero, A.G., Wybraniec, S. (2013). An overwiev
of the Kjeldahl method of nitrogen determination. Part I. early history, chemistry of the
procedure, and titrimetric finish. Critical Reviews in Analytical Chemistry, 43(4):178-223
Singh, S., Dutta, S., Inamdar, S. (2014). Land application of poultry manure and its influence
on spectrofluorometric characteristics of dissolved organic matter. Agriculture, Ecosystems
and Environment 193:25-36
Yadava, U.L. (1986). A rapid and nondestructive method to determine chlorophyll in intact
leaves. HortSci. 21:1449-1450
WEB 1: http://www.italpollina.com/en/Product/9/ITALPOLLINA 15th of Oct. 2014.
WEB 2: http://www.italpollina.com/en/Product/4/DIX_10_N 15th of Oct. 2014.
sa2015_p0407
290
50th Croatian and 10th International Symposium on Agriculture