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Fusion News Issued by the EFDA Close Support Unit Garching, Germany www.efda.org Newsletter Volume 4 May 2010 Francesco Romanelli new EFDA leader EFDA Integrated Tokamak Modelling Task Force Major upgrade to MAST diagnostic Agence ITER France – ITER’s home support The joy of being part of Fusion Expo On March 23rd, the EFDA Steering Committee appointed Francesco Romanelli to the role of EFDA Leader. For the time being, he will also remain the EFDA Associate Leader for JET. Fusion News talks to him about his future plans (page 2). (Photo: JET) Beryllium Handling Facility established at KIT EFDA during FP7 – Reinforced coordination of physics and technology in EU laboratories Part 6 Integrated Tokamak Modelling Task Force (ITM-TF) The path that leads toward using fusion as a sustainable source of energy for the future goes via the exploitation of the next generation of fusion devices, and in particular, ITER, which is designed to demonstrate the scientific and technical feasibility of fusion. In order to predict ITER performance in terms of energy production and to guarantee optimal operation, high level physics modelling and simulations are required. FN1001_12S.indd 1 Modelling of a tokamak experiment is necessary to fully comprehend the experimental results, furthermore, benchmarking models against each other (for verification) and the experiment (for validation) increases their prediction capability in view of the realisation of a fusion reactor. Continued on page 9. 27.04.10 11:08 News EFDA Fusion News Francesco Romanelli new EFDA leader Francesco, what is your strategy for EFDA? EFDA should implement goal-oriented activities in which the resources of a single Association are sub critical and the coordination role of EFDA is able to bring obvious added value and also facilitate and promote the emergence of scientific excellence. JET is an example of an activity that could not be performed without EFDA coordination, but we need to look towards future activities in other areas, such as DEMO and the satellite programme. Which DEMO related tasks do you see implemented under EFDA? Europe needs to start working on the conceptual study of DEMO as soon as possible. Other ITER partners have already established much clearer ideas on what DEMO should be like. The conceptual design activity for DEMO should be carried out within the EFDA system, along with the qualification of the main technologies and pre-qualification of industry. At a later date, the engineering design activity, such as prototype building, and the construction of the machine should be carried out by F4E. Can you specify the tasks of EFDA within the satellite programme? European scientists should start getting involved in the preparation of the JT60SA exploitation right now. Construction is obviously under the responsibility of F4E, but the preparation of the exploitation should be carried out under EFDA. The possible construction of a European satellite is a related factor. Following on from the results of the Group of Experts on the Satellite Tokamak, EFDA will have to investigate the feasi- F4E News – the Fusion for Energy newsletter With updates on scientific and technological progress, articles about current procurements, as well as news bility of such a device. These are the two areas in the satellite programme that EFDA should be addressing. It sounds as if you are foreseeing a larger EFDA in the future? Yes, we should increase the activities within EFDA, focussing on issues where the role that EFDA plays is essential because it brings added value as a result of coordination, which is the case in areas where a single Association is sub-critical. Where do you see the future challenges for EFDA? The future challenges for EFDA lie in the ability to mobilise a significant amount of resources from the European Commission and the Associations in order to achieve well defined goals. The original spirit of EFDA implies that Associations and the Commission jointly define the fields in which they wish to invest and agree on the resources that all partners are prepared to make available in order to achieve this goal. EFDA has been successful in achieving this with JET and the High Performance Computing Implementing Agreements and should be capable of doing so in the areas that I have mentioned above. How do you see the future cooperation of F4E and EFDA? There should be a lot of synergies between F4E and EFDA. EFDA is prepared to help F4E with all the support that might be required for when it comes to the construction of ITER. The important point is that we see EFDA and F4E as complementary organisations in which F4E has the duty of bringing forward project oriented activities, such as the ITER construction, and in which EFDA is capable of conducting goal oriented activities with a more programmatic value. What challenges and opportunities lie on events and publications, Fusion for Energy’s newsletter, F4E News, was launched in December last year. F4E News aims to inform the fusion community, energy and the environment policy makers, industry and small and medium enterprises about Europe’s contribution to ITER and the progress of the project. F4E News is published quarterly and is currently available electronically. Issues are sent via email to subscribers or can be accessed from the F4E website www. fusionforenergy.europa.eu. In future, paper versions of the issues will also be available. FN1001_12S.indd 2 in your current position as both EFDA leader and Associate Leader for JET? I think the opportunities are very important because holding both positions means that I can ensure maximum integration within the EFDA programme. There are a number of examples in all programmatic areas where EFDA is active and in which we need to maximize synergies with the view to maintaining a single forum for programmatic discussion within EFDA. At the next meeting of the Steering Committee you will propose a new structure for the EFDA top management – what are your objectives? I think the important point is the effectiveness of the organisation. Even more important is that both Associations and the European Commission are willing to invest both financial resources and good scientists and engineers in EFDA thus leading to projects within the EFDA system. With good organisation and good people in place, I think the challenges can easily be solved. Speaking of good people: Does fusion attract enough young scientists? The scientific challenges posed by fusion are certainly attractive to scientists. EFDA has an ambitious programme designed to train around forty young professionals per year by means of fellowships and goal oriented training. It is necessary to do this because we need to educate the generation that will be first in line to exploit ITER and then build DEMO. More information about Francesco Romanelli can be found here: http://www.efda.org/news_and_ events/latest_news.htm#4 http://www.efda.org/news_and_ events/downloads/efda_newsletter/nl_2006_04.pdf To find the most recent issue of F4E News, please visit: http://fusionforenergy.europa.eu/ f4enews/march2010/ Want to subscribe? Send an email to F4ENews@f4e.europa.eu and specify whether you want your copy of F4E News in an electronic or paper format. Have you got an idea for an article or would you like to publicise an event in the calendar? Contact Samina Shamsie, email: samina.shamsie@f4e.europa.eu Samina Shamsie, F4E 27.04.10 11:08 EFDA Fusion News The joy of being part of Fusion Expo Saša Novak, a member of Fusion Expo Team in the Slovenian Fusion Association and a materials scientist at the Jožef Stefan Institute, recounts her personal excitement at being involved in management and hosting Fusion Expo. Every time Fusion Expo is on the road, one of my favorite tasks is clicking on the yellow star in the morning. That takes me to www.fusion-expo.si a site which is regularly updated by Melita Lenošek, the project leader and the main driving force of the Fusion Expo team. On the first day I usually see that the truck has just arrived safely on site or I fi nd pictures of the team unloading the boxes. A day or two later, I am looking at pictures of bright faces and happy smiles, people wearing ties and skirts, and I am wondering who might be in the fi rst row: A minister for science or perhaps a city major or a dean? Is this lady a journalist? No, that’s probably the one who holds a microphone. I can easily recognise the organizer by his or her most enthusiastic smile. Oh, yes, and here are Melita and the boys who just fi nished another great job. They have changed out of their “Fusion Expo Team” t-shirts into smart jackets and they seem happy, too. Over the next days, I frequently click on the yellow star for news. Sometimes I find reports in journals, a link to a TV broadcast of the event or a new set of pictures. These I like the most. I enjoy looking at the photos of young children working hard to produce more energy on the bicycle than their schoolmates. I like seeing the blue reflections of the plasma tongues in the visitor’s admiring faces and a crowd of hands reaching out to touch the plasma ball. And I relish looking at a group of people of all different ages deep in thought standing listening to a guide who cannot and doesn’t even try to hide that he enjoys his role guiding people through the exhibition. What can be better than sitting at the computer, seeing that everything goes well? Being aware that as I watch, more and more European citizens understand the concept of using fusion as an energy source for the future and more and more people are telling their friends about the construction of ITER? What can be better than knowing that more and more journalists understand our quest and may be in a position to write about fusion? That more and more poli- FN1001_12S.indd 3 ticians are considering fusion a viable option and might one day join in with a supportive statement at the right occasion? Oh yes! For me, even better than just observing the “reports” from the exhibitions around Europe, is playing an active role by hosting such an event. I can tell you: it is a fantastic feeling, taking one last look around the hall on the evening of the opening ceremony: is everything ok, who is in the audience, is the director here, how many journalists have come? And finally to signal: Let’s start! It’s nice secretly observing the effect that the work we have put in has on the faces of our guests during the ceremony. And after all, it’s a pleasure taking pictures during the event and uploading them to the web page, knowing that somewhere else someone might click on the yellow star to follow the Fusion exhibition from their computer. There are a number of people who know exactly what I am writing about. Last year’s hosts will probably have very fresh memories of the excitement of hosting the Fusion Expo: Prof. Gulbinski in Koszalin, Prof. Dabrowski in Szczecin, Prof. Broda in Lodz, Dr. Jarozs in Katowice, Dr. Boilson in Dublin and Ms. Whelan in Cork. Let us know if you would like to share the joy. Fusion Expo dates: 27th September – 1st October 2010: Oporto, Portugal (simultaneously with SOFT2010) 18th October – 15th November: Brussels, Belgium EU fusion research website relaunched The EU fusion website has been fully updated as part of the relaunch of the energy research website of the European Commission. The most significant change is the recently introduced discussion platform enabling visitors to voice their ideas and comments on nuclear research in Europe and on fusion in particular. The site also offers researchers 200 pages containing complete information with regard to all of the funding opportunities in the energy and nuclear energy fields at EU level. Don’t forget to keep a close eye on the fusion subpage, as it will soon host video footage from a subsidiary event at the Copenhagen climate conference focusing on low carbon technologies. There, Prof. Sir David King, Director, Smith School of Enterprise and the Environment, UK, and former chief science advisor to the UK government, gave a speech on “the future of fusion power and its role in fighting climate change”. Thanks to Dr. Takis Ageladarakis, EU Commission, for his input EU energy research page: http://ec.europa.eu/research/energy/index_en.cfm Fusion subpage: http://ec.europa.eu/research/energy/euratom/fusion/index_en.htm 27.04.10 11:08 Associations EFDA Fusion News Beryllium handling facility established at Karlsruhe Institute of Technology In January 2009, the Karlsruhe Beryllium Handling Facility (KBHF) was founded as part of the cooperation between Goraieb Versuchstechnik (GVT) and the Karlsruhe Institute of Technology (KIT). Located at KIT’s North Campus, the laboratory is unique in Europe for handling and processing beryllium. It offers a user facility which enables the construction of various experiments, beryllium storage facilities as well as a laboratory for beryllium alloys. KBHF is qualified to handle large amounts of the hazardous material and plans to set up a small scale production line for beryllium alloys. KBHF maintains close contact with Brush Wellmann Inc. (BWI), the market leader for beryllium and beryllium products. KIT, KBHF and BWI are preparing a cooperation contract that will – among several other aspects – enable the production of larger amounts of special beryllium alloys if necessary. Beryllium is both an attractive and nasty substance: lighter than Aluminium, harder than steel and robust up to high temperatures. However, it is also highly toxic: beryllium dust can harm human skin and lungs badly, its effects occurring sometimes only decades after the exposure. Once manufactured into FN1001_12S.indd 4 Handle with care: KBHF’s Beryllium storage facility BELLA (Photo: A. Goraieb, KBHF). a solid work piece, beryllium is as harmless as any other piece of metal, but processing needs to be handled with the greatest of care. At the moment, the main consumers of beryllium are the military, aerospace and electronics industries – the latter using mostly beryllium-copper alloys. The lightweight metal is a very attractive substance for use in fusion reactors. Its hardness, its high melting point of 1284 °C and its low atomic weight make it an almost perfect material for the reactor’s first wall (See FN December 2009). Furthermore, beryllium acts as a neutron multiplier when hit by fast neutrons from the fusion reaction, transforming into helium plus two neutrons. One of the two current concepts for tritium breeding blankets is therefore based on beryllium pebbles (See FN May 2009). KBHF’s roots go back more than 16 years, when Aniceto Goraieb was about to finish his diploma thesis investigating the thermal conductivity of beryllium. The facility at which he conducted the experiments closed down and he was forced to set up his own beryllium laboratory on the premises of Forschungszentrum Karlsruhe. As other materials researchers turned to him seeking advice and support, his lab slowly became a beryllium handling and consulting enterprise, building up in-depth expertise on this hazardous material. Today, Goraieb Versuchstechnik (GVT) is the only organisation in Europe that plans, constructs and conducts beryllium experiments. It cooperates closely with fusion research at KIT, for instance, by developing fabrication techniques for beryllium-titanium pebbles as potential components for the tritium breeding test blanket modules. GVT manages the KBHF and advises other organisations when it comes to setting up their own beryllium facilities. Since 2003, GVT has been developing new beryllium alloys in cooperation with KIT. These so-called beryllides are still widely unknown and offer a huge potential for future materials. Hence, GVT plans to set up a labscale production facility within KBHF, which enables the handling of around 100 kg beryllium powder. KBHF aims to drive the development of beryllium technologies and has initiated workshops about “Beryllium Opportunities on New Developments” (BeYOND), bringing industrial and scientific partners together. The first workshop was held on the 13th of November 2009 at KIT. The next workshop will take place as a satellite meeting of SOFT 2010 in Porto, Portugal on October 1st 2010. Thanks to Dirk Radloff, KIT and Aniceto Goraieb, GVT for their input For more information, please see: http://www.kbhf.org/index.html http://www.kit.edu www.versuchstechnik.de 27.04.10 11:08 EFDA Fusion News One of the last coils is placed onto W7-X’s plasma vessel (Photo: C Rüth, EFDA) All coils put in place at Wendelstein 7-X On March 24th, Professor Thomas Klinger, scientific director of Wendelstein 7-X, announced the completion of an important project milestone: The last coil had been threaded onto the plasma vessel. The Fusion News team was fortunate to have visited the site the week before. Here is a personal account from what can only be described as an impressive construction site. The scene is a Wednesday morning in the assembly hall of the Wendelstein 7-X (W7-X) project at IPP Greifswald: While the visitors are still overwhelmed by the sheer size and complexity of the construction site, a camera team is busy setting up its equipment to produce 3Dfootage of the installation of one of the last coils onto the plasma vessel. Finally the star of the film – a strangely shaped non-planar superconducting coil – is lifted up by the crane, turned around, given one last clean and hoisted over to the other side of the hall. One can virtually feel the quiet routine of the workers pervading through the room as they thread the 3.5 metre high and six ton heavy coil onto the plasma vessel with, in some places, mere millimetres to spare. Next door in the torus hall, the fi rst of fi ve modules that make up the entire plasma torus has already been FN1001_12S.indd 5 given the outer steel shell with as many holes as a piece of Swiss cheese. The magnets and inner vessel have vanished inside the steel shell and, after all of the ports have been fixed to the holes, the device will look like a huge, ringshaped object with innumerable legs sticking out in all directions. Dr. Wegener, who oversees the entire assembly, outlines the complexity of the construction: The machine weighs 725 tons, has a diameter of 16 metres and features 254 ports. Each of its five modules contains 1000 main components. When the device is finally commissioned in mid Large copper mirrors guide the ECRH system’s powerful microwaves through free air (Photo: Anja Richter Ullmann, IPP) 27.04.10 11:08 EFDA Fusion News Associations 2014, around 700,000 man hours will have gone into the construction project. The first plasma is expected to be generated in 2015. The next day we find ourselves in a long hallway which serves as a wavechannel for the electron cyclotron resonant heating (ECRH) system’s microwaves: What is a familiar sight from optical benches, i.e. mirrors sending light along certain paths, occurs here at a considerably larger scale. Copper mirrors and polarisers combine ten microwave beams, each with one megawatt of power and around 10 cm in diameter, into two large beams and send them into the plasma vessel. The ECRH system benefits from the new site, as the buildings could be adapted to suit to its needs, whereas most fusion experiments are restricted in space and need to make use of less effective waveguides rather than sending the microwaves through free air. ECRH is intended to be used as the main heating system for Wendelstein 7-X, just like at ITER. Hence the Greifswald team also conducts tests and experiments for ITER. It is currently testing a fast beam switch that ITER will need to prevent the formation of instabilities. Further information can be found in the latest W7-X Newsletter: http://www.ipp.mpg.de/ippcms/ eng/for/publikationen/w7xletters/ index.html. Learning from Wendelstein 7-X On March 17th and 18th, the JT60SA and W7-X teams met in Greifswald to exchange ideas and hear about the lessons learned during Wendelstein’s construction phase. Nine of the thirteen visitors came from the JT-60SA group in Garching, while four came from Japan. Dr. Manfred Wanner, Seconded National Expert of IPP at the JT-60SA team and responsible officer for cryogenics, had been working in the W7-X project from 1996 until end of 2007. He initiated the meeting with the intention to support the young JT-60SA team to learn from the experiences gathered from the W7-X. Dr. Rem Haange, technical director at W7X, chaired the sessions of the event. The timing was well chosen, as one of the last coils was being installed on W7-X, thus giving the JT-60SA team a chance to still see all stages of the assembly processes. At the meeting, the W7-X team provided a deep MAST’s Thomson scattering diagnostics has been upgraded from four to eight lasers (Photo: CCFE) FN1001_12S.indd 6 insight into their experiences with the organisation and management of such a complex scientific project, focussing, on lessons learned during the design, construction as well as testing and assembly of the superconducting coils. The team also touched on the overall assembly process, providing first hand information on issues such as special vacuum techniques and metrology. Furthermore, it provided detailed information on the organisation of the assembly process, including documentation, quality management and processing orders for main components, and problems that had to be solved, such as the practical handling of tolerances or suitable welding techniques. Other topics of the meeting included the construction of the supply systems such as the helium refrigeration plant and the power supplies for the superconducting coils. The JT60SA team was very grateful for the open and fruitful discussion that has helped to establish valuable contacts between both teams and uncovered interesting aspects that are of interest to both projects and that will be discussed subsequent to this meeting. Thanks to Manfred Wanner for his input Major upgrade to MAST diagnostic The MAST experiment, located at Culham Centre for Fusion Energy (CCFE), now has the world’s most advanced system for recording the plasma temperature and density profiles. Thomson scattering is used to obtain local measurements of electron temperature and density inside the hot plasma – which can reach over 20 million °C in MAST – by measuring the scattering of light from laser beams fired into the plasma. This is done by imaging the laser beam in the plasma into optical fibres via a large collection lens. (Figure 1). The fibres transfer the light from each spatial location to a respective spectrometer. While the previous system imaged 30 – 50 mm of laser light into one spectrometer, the large lens of the upgraded system collects enough light to image 10 mm of laser light per spectrometer, leading to a higher resolution. With this new diagnostic, MAST measures at 130 spatial points using 27.04.10 11:08 EFDA Fusion News Figure 1: The MAST Thomson scattering diagnostics system. Eight Nd:YAG lasers follow a beam path through the plasma (yellow).”. A large lens (orange) collects light coming from the laser. Depending on their exact location along the laser beam, the light beams reaching the lens are directed into individual optical fibre. That way data from 130 separate locations at a resolution of only 10 mm can be recorded. The system employs an additional lens (green) to measure at the plasma edge. (Picture: CCFE) The new collection lens at MAST’s Thomson scattering diagnostics weighs 100 kg and is the largest of its type in any fusion experiment (Photo: CCFE) 130 spectrometers. The diagnostic can now perform high resolution measurements over the whole radius of the plasma, while previously this resolution could only be obtained at the outer edge of MAST. One of the system’s primary goals is to measure the size and structure of magnetic islands that affect the confinement of the plasma and reduce the fusion energy output. This can now be achieved at high resolution and thus detailed profiles of the evolution of many plasma phenomena have already been recorded. The upgrade has also improved the temporal resolution by increasing the number of lasers used from four to eight, effectively dou- FN1001_12S.indd 7 bling the number of time points in a measurement burst during a MAST plasma pulse. A ‘smart’ triggering device can now synchronise the lasers to the exact time of specific ‘events’ during the pulse, such as the formation of the plasma or the injection of fuel pellets. Researchers from the University of York’s Plasma Physics and Fusion Group, in collaboration with CCFE, will exploit the upgraded system to confirm the theoretical principles of plasma behaviour. They are now able to run experiments on MAST directly from York, using a new remote control room recently installed at the university. A better understanding of the processes occuring in plasmas will help to improve the performance of future fusion devices such as ITER. Dr Mike Walsh, who was the CCFE project leader and who has now moved to the ITER Organization to become Head of the Diagnostics Division, explained how the MAST Thomson scattering diagnostic will give researchers an extremely detailed view of the evolution of the plasma: “We expect the system to throw up new physics and allow us to observe effects we have never been able to see in plasmas before.” The £2 million upgrade, jointly funded by the UK Engineering and Physical Sciences Research Council, University of York and the Northern Way collaboration of Regional Development Agencies, was completed in September 2009 and the diagnostic is already providing data that exceeds its design specifications. Jennifer Hay and Rory Scannell,CCFE 27.04.10 11:08 EFDA Fusion News Associations Agence ITER France – ITER’s home support The appointment of Jérôme Pamela as head of Agence ITER France (AIF) in January 2010 can be seen as returning home. Upon visiting the ITER site several days after his arrival, he was able to measure the extent of the work already completed at Cadarache as part of France’s host commitments. This is a project he is very familiar with as he was responsible for coordinating the initial technical studies which were launched in 1995 to prepare for Cadarache’s candidacy as the host of the ITER project. Since the Cadarache site was chosen for ITER in 2005, work has progressed smoothly in the Provence region. The International School in Manosque, with classes ranging from pre-primary to the baccalaureat, is now open and welcoming children. The approximately 100 kilometre stretch of road between Fos-sur-Mer (near Marseille) and Cadarache has almost been entirely developed to handle the heavy duty traffic load. Agence ITER France is getting ready to hand over the site to the ITER Organization, which is now fully-serviced and ready to start the construction of the machine. More than 2.5 million cubic metres of material – equivalent to the Great Pyramid of Cheops – was used to build the huge platform which stretches across forty hectares and upon which thirty-nine buildings will be built over the next five years under the responsibility of the European Domestic Agency, Fusion for Energy (F4E). In excess of twenty kilometres of piping has been installed for the various water systems required on site (rainwater drainage, tokamak cooling water, facility effluents, etc.), not to mention the almost 12,500 m² of office space which has been made available to the ITER Organization and F4E. This summer, Agence ITER France will start building a large office building about 200 metres long and capable of accommodating 460 people. “The commitments France made as host of the ITER project have been kept. Agence ITER France will make sure that this continues in the future, while developing various activities through which France, as host, hopes to support the project during the construction phrase,” declared Jérôme Pamela. This will be done by setting up activities serving the project, by preparing for the arrival of the first heavy components, by helping industry to set up in the region and by continuing to facilitate the integration of ITER personnel in France. Sylvie Andre, Agence ITER France Germany looks at the future of energy “At the age of 16 I taught girls to dance, today I’m teaching hydrogen atoms”. Prof. Dr. Günther Hasinger, scientific director of MaxPlanck-Institute for plasma physics (IPP), is one of four topical ambassadors that have put their faces to the German science year 2010, “The Future of Energy”. Throughout the year long event, the German Ministry of Education and Research will be showing how scientists in Germany and all over the world are already working on solutions to ensure secure, economical and climate friendly energy supplies in the future. “At the age of 16 I taught girls to dance, today I’m teaching hydrogen atoms”. IPP director Günther Hasinger In her monthly video is one of the topical ambassadors of the German science year 2010, “The future of energy”. message, Federal Chancellor Angela Merkel heralded questions such as how would he have ergy in a way that makes visitors realise the science year and highlighted the just how precious energy is. significance of fusion research. She explained if he had been an expert on then also visited the IPP Greifswald Julia Sieber, IPP tokamaks rather than on stellarators. site on February 1st. Fusion research Fusion research is widely represented in Chancellor Merkel’s video message: is a “sign of the future” and Gerthis year of energy. Among other events, http://www.bundeskanzlerin. many may make fusion history with IPP has contributed to an exhibition-ship de/nn_707282/Content/DE/ the unique project Wendelstein 7-X, Podcast/2010/2010-01-30-Videothat tours with “energy” along German Merkel said. The Chancellor holds Podcast/2009-01-30-video-podand Austrian water ways, stopping in 30 a Ph.D. in physics and was not only cast.html cities. The floating science centre hosts a able to follow the speech given by Website of the science year: IPP’s Prof. Thomas Klinger, but also magnificent hall, its stage displaying the www.zukunft-der-energie.de came up with a number of interesting current knowledge and research on en- FN1001_12S.indd 8 27.04.10 11:08 EFDA Fusion News EFDA during FP7 – Reinforced coordination of physics and technology in EU laboratories Part 6 Pär Strand is an Associate Professor at Chalmers University of Technology, Gothenburg, Sweden and Integrated Tokamak Modelling Task Force (ITM-TF) has been acting as the Leader of the ITM Task Force since Continued from front page Tokamak physics covers a wide range of areas such as plasma turbulence, magneto-hydrodynamics (MHD), radiofrequency (RF) wave propagation, plasma-wave interaction and plasma-wall interaction. Moreover, the operation of a high performance tokamak requires a number of technological elements including super-conducting magnets, RF wave generators and antennas, fast ion sources and accelerators, plasma diagnostics and real-time control schemes. In addition to the tight coupling of the physical phenomena among each other, technology and physics are also strongly linked: RF wave launching conditions depend on the antenna characteristics, plasma equilibrium is controlled by external magnetic field coils and the interpretation of measurements requires the knowledge of the diagnostic hardware. Although individual models exist for most of these elements and components, a realistic modelling of a tokamak experiment ought to cover all of these physical and technological aspects, whilst taking into account the complexity of their interactions. This requirement results in the emergence of the Integrated Modelling concept. A wide choice of models, using different levels of sophistication in the 2006, after holding a deputy position since the start of the project. He is also the Coordinator of the EUFORIA – “EU Fusion for ITER Applications” project which is funded under the EU FP7 Capacities programme. Dr. Strand is also the ITM-TF representative on the HPC-FF Board and Chairs the ITER Integrated Modelling Expert Group advising ITER Fusion Science and Technology on modelling issues. Pär Strand’s vita can be found here: http://www.efda.org/about_efda/activities-itm-paer_strand. htm physics description, can be applied to describe tokamak plasma phenomena prior to the transcription of the mathematical model into a numerical code. Besides, different numerical methods can be used to solve the same type of mathematical model resulting in an even wider choice of numerical codes for the fusion plasma community. Some of these codes have been extensively verified and validated and integrated into simulators for specific purposes. However, they are often only suited to the geometry settings and experimental data from a specific tokamak and seldom adopt generic descriptions for subsystems (e.g. heating, diagnostics) which match any given experimental device. Moreover, each simulator uses its own format for general input/output and interfaces to its internal modules. This makes the Lars-Göran Eriksson has worked at the JET Joint Undertaking and at CEA Cadarache. He was appointed ITM deputy task force leader in October 2006. He is now at the European Commission in Brussels and is the Directorate General for Research Unit J4 – Fusion Associations Agreement. His duties still include the deputy leadership of the ITM task force. Lars-Göran Erkisson’s vita can be found here: http://www.efda.org/about_efda/activities-itm-lars_ goeran_eriksson.htm FN1001_12S.indd 9 27.04.10 11:08 Focus on EFDA Fusion News exchange of data and physics modules (code portions containing a physical model) between codes tedious, thus slowing down the benchmarking efforts and the development of physics modules that may be shared. In view of ITER exploitation and the development of future fusion reactors, the challenge is to provide an integrated simulator that meets the reliability standards required by the operation of a nuclear device, and thus enables the transparent use of the available numerical models. The European Integrated Modelling approach The choice of Integrated Modelling made by the ITM-TF is unique and original. It entails the development of a comprehensive and completely generic tokamak simulator that includes both the physics and the machine and can be used for any fusion device. The simulation platform will be fully modular, flexible and independent of a programming language. The choice of modularity implies that each module contains a single physical model and that the communication between the modules is standardised. A set of common rules clearly specifi es the format of the data that is to be consistently exchanged between modules (data-structure). The complexity of coupling the codes is therefore transferred to the defi nition of a datastructure which should be generic (able to describe and exchange information concerning both physical quantities and technical objects, not assuming the origin of those) and extendable to allow for the integration of new physics, as FN1001_12S.indd 10 Rui Coelho is an assistant researcher at the Instituto Superior Técnico of Lisbon (IST) and has been assigned to the Theory and Modelling group of IPFN since 2005. This group investigates non-linear MHD plasma instabilities and real-time digital signal processing on plasma diagnostics. He is the contact person for the EFDA ITM-TF and MHD Topical Group at the IST Euratom Association. He joined the ITM-TF Leadership as deputy in mid 2008 and is charged with the coordination of the Experimentalists and Diagnosticians Resource Group (EDRG). Rui Coelho’s vita can be found here: http://www.efda.org/about_efda/activities-itm-rui_coelho.htm well as more elaborate machine geometries and experimental data in the future. The Consistent Physical Object (CPO) concept has been developed to this purpose: CPOs are the only blocks of consistent data exchanged between physics modules during an integrated simulation. The definition of CPOs for the different classes of physics codes derives naturally from the input/output logics of a physics problem; CPOs are identical for all modules addressing the same physics problem and produced as a whole by a single module, thus ensuring the consistency of the data. A CPO might be, for instance, the plasma equilibrium data that is made up of plasma profiles, plasma boundary, a flux surface coordinate system and other data. Thanks to this conceptual paradigm in Integrated Modelling, the physics and programming aspects are separated so that an external or wrapping software can deal with the exchange of data, the link to the experimental database and access to the simulation platform. Code developers wishing to integrate their code into the ITM simulation platform must provide it in a modular form with the CPOs as input and output arguments. Libraries written in different programming languages and developed by ITM, automatically handle the exchange of CPOs between modules. An open source software (KEPLER) featuring a user-friendly interface allows the user to choose, add and link together the physics modules and launch the desired integrated simulation (a simulation workflow). A cen- tral computer platform was made available in 2008 on which the ITM suite of tools is tested and released – the “Gateway” hosted at ENEA/CRESCO. It allows ITM-TF users to run simulations locally or within the framework of GRID (a grid of geographically distributed supercomputers) or High Performance Computer environments. Additionally, the High Performance Computer for Fusion (HPC-FF) at FZ Jülich was made available in autumn 2009. ITM-TF work programme and achievements The Integrated Tokamak Modelling Task Force was created in 2003 with the task of coordinating the development of a coherent set of European simulation tools to be benchmarked on existing tokamak experiments, with the ultimate aim of providing a validated simulation package for ITER exploitation. ITM-TF is divided into four Integrated Modelling Projects (IMPs) that focus on the following areas of physics: plasma equilibrium and MHD, transport code and whole discharge evolution, transport and micro-instabilities and finally, heating, current drive (H&CD) and fast particles. Their work programmes reflect some of the needs expressed by ITER, most of which require an Integrated Modelling platform: • IMP12: Mitigation and avoidance of disruptions (in coordination with EFDA Topical Group MHD and PWI TF), ELMs and other instabilities; 27.04.10 11:08 EFDA Fusion News • IMP3: Pellet injection, ELM triggering; • IMP4: Effects of edge turbulence on core energy; momentum, fuel and impurity confinement; consistent characterisation of turbulent transport over the full wave spectrum; • IMP5: Coupling between sources and energetic particle effects; coupling of energetic particle instabilities to MHD. The “Infrastructure and Software Integration Project” (ISIP) is in charge of the development of the code platform and the implementation of the ITM data-structure and tools. Two additional subgroups coordinated by the TF leaders guarantee the link with the experimentalists and the provision of the experimental databases: The “Atomic, Molecular, Nuclear Surface” Data (AMNS) and the “Experimentalists and Diagnosticians Resource Group” (EDRG). In 2007, the “ITER Scenario Modelling Working Group” (ISM) was established as part of ITM-TF with the aim of assisting the ITER International Organisation in systematic predictive modelling of all reference scenarios, using the major existing integrated modelling tools, whilst the ITM code platform was in development. ISM produced very valuable work in terms of both code cross-comparisons and validation and scientifi c publications, addressing a wide range of physics issues for ITER. ISM activity will continue in 2010 in collaboration with ITPA (International Tokamak Physics Activity) and the international fusion community, aiming to include ITM codes and modules as they become available. ITM-TF is working in close collaboration with the EUFORIA – “EU Fusion for ITER application” project towards creating transparent access to capacity and capability computing. A central ITM-TF project is the development of the European Transport Solver (ETS). The project is an exceptional one in that ITM-TF usually only coordinates code development. It is motivated by the fact that none of the existing transport codes meet all of the ITM requirements, namely modularity, flexibility and standardised interfaces. In terms of the physics, the ETS is designed to solve the standard set of one-dimensional time-dependent equations which describe the evolution of the core plasma, including several ion species (impurities). The solver itself is designed with a modular approach enabling the separation of the physics from the numerics, thereby facilitating the testing/usage of the numerical schemes that best suit a particular scenario. During the first phase of ITM-TF, surveys and cross-verification of the available models and numerical codes were performed within the individual IMPs and the data-structure was extensively discussed. Equilibrium, linear MHD stability, core transport and RF wave propagation, as well as the poloidal field systems and some diagnostics were the first topics addressed. Data-structures have been finalised for these and are being expanded to address, among others, non-linear MHD, edge physics and turbulence as well as neutral beam propagation. Alongside the development of the physics concepts, ITMTF has produced tools to manipulate the data-structure and use it in fully flexible and modular simulation workflows. The ITM-TF has now achieved the development of an initial release version of a fully modular and versatile simulator containing all essential functionalities. The simulator is now ready to be used for the first physics applications. In 2010, the validation of tools can start: the database is being filled with machine descriptions (JET, Tore Supra, MAST, FTU, FAST and AUG) as well as experimental data (some discharges of Tore Supra and JET) and modules from the different IMPs are available for integration into the transport solver. The next few years will see the validation of the simulator for a complete discharge based on existing experimental data with the available modules, the integration of more quantitative physics models (“ab-initio”) and the integration of the entire modelling of the device. Gloria Falchetto, IRFM, Rui Coelho, IST, Christian Konz, IPP ITM-TF: http://portal. efda-itm.eu/portal/ ITM Gateway: http:// www.efda-itm.eu/ Gloria Falchetto holds a permanent position at the CEA Research Institute on Magnetic Fusion (IRFM, Cadarache, France) where she is part of the “Transport, Turbulence and MHD group” which is working on turbulence simulations and modelling. She was appointed deputy leader of ITM Task Force in mid 2009, after being deputy leader of IMP4. Gloria Falchetto’s vita can be found here: http://www.efda.org/about_efda/activities-itm-gloria_falchetto.htm FN1001_12S.indd 11 27.04.10 11:08 JET Tailoring JET’s web page In mid December the revamped webpage www.jet.efda.org went online. It contains new features such as RSS feeds for news and the “picture of the week”. Additional search functions in the news archive and on all pages should help users finding the information required. A procedure to request brochures easily has been added. The newsletter “JETInsight” now comes in hardcopy and online, providing additional information where suitable. Moreover its subscription procedure has been simplified. In the three months since the new web page went online, the number of subscribers to JETInsight has been increased by 37 per cent. A closer look into the statistics reveals that users have immediately taken one feature on board which is the RSS Feed. Nearly 50 % enter the page through this service. For those of you who have never used RSS, you should give it a try. Its beauty is the easy way to keep updated whenever any new content appears on the page you subscribed for. The device is your choice; your computer, smart- or iPhone will do. FN1001_12S.indd 12 A surprisingly high number of visits has been noticed in February with more than 14,000 unique visitors. As speculation is allowed two new regularly items on the web page may have gathered increased interest in EFDA JET. As in previous issues of Fusion News reported, JET has entered a nonexperimental period, called shutdown. Some people (still) think JET won’t perform any experiments from now on. So we took the opportunity to set up the “shutdown weekly” to inform on what is going on at the JET Facility during a 65 week duration of maintenance and upgrading. The other new feature is the “picture of the week” which highlights different aspects of the fusion facility each week. The revamp of the EFDA JET webpage represents the first step to improve the pages for more and more people who turn their back on traditional media. Now, with a comfortable Content Management System in use, it is easy to tailor the Web page according to users’ likes and dislikes. Suggestions are welcome! Petra Nieckchen, EFDA-JET ISSN 1818-5355 For more information see the websites: http://www.efda.org http://www.jet.efda.org http://www.iter.org EFDA Close Support Unit – Garching Boltzmannstr. 2 D-85748 Garching / Munich – Germany phone: +49-89-3299-4263 fax: +49-89-3299-4197 e-mail: christine.rueth@efda.org editors: Christine Rüth, Örs Benedekfi layout: dolp & partner © Francesco Romanelli (EFDA Leader) 2010. This internal newsletter or parts of it may not be reproduced without permission. Text, pictures and layout, except where noted, courtesy of the EFDA Parties. The EFDA Parties are the European Commission and the Associates of the European Fusion Programme which is co-ordinated and managed by the Commission. Neither the Commission, the Associates nor anyone acting on their behalf is responsible for any damage resulting from the use of information contained in this publication. 27.04.10 11:08