News: Energi related to Chalmers University of TechnologyTue, 20 Feb 2018 11:04:17 +0100 profile in renewables returns<p><b>​After 35 productive years as a researcher, inventor and entrepreneur, Mats Leijon has returned to Chalmers, where he once started his career, now as a Professor in Electrical Engineering.</b></p>​“This is a new and exciting step for me”, Mats Leijon says. “I see myself as a resource for younger researchers, with the purpose to contribute with my knowledge where I can make the most of it.”<br /><br />His career started with studies in electrical engineering at Chalmers in the 1980s. After having defended his doctoral thesis in high voltage engineering in 1987 he started working at ABB in Västerås. During his 13 years at the company he had several positions and worked as head of research, developing technology for measurements of diagnostics and monitoring of insulation systems and electrical power devices. In addition, he has invented and developed products in power generation. Most known is perhaps the Powerformer, a high voltage generator for connection to the grid without any intermediate transformer.<br /><br /><strong>Developing renewables</strong><br />Since 2000, Mats Leijon is a Professor in electrical science at Uppsala University. He has got about 1500 patents and has published more than 300 scientific articles. Developing renewable energy sources by using waves, wind and tidal currents have become his specialty. In parallel he has started the company Seabased, which plans, builds and installs complete, grid-connected wave parks at sea. Research and demonstration facilities are located outside Lysekil.<br /><br />He is now phasing out part of his many commitments to be able to take on the assignment at Chalmers.<br /><br />&quot;I look forward to combining theory and practice to a larger extent than I have been able to do previously in academia&quot;, says Mats Leijon. “Here at the division of Electrical Power Engineering, there are good laboratory activities.”<br /><br />In his opinion, setting high goals is crucial to success.<br /><br />“First of all, I'm going to familiarise myself with the research activities here, and then apply for funding to do exciting research, but it is still too early to say in what areas this will be.”<br /><br /><strong><img class="chalmersPosition-FloatRight" src="/SiteCollectionImages/Institutioner/E2/Profilbilder%20Elkraftteknik/Mats-Leijon_300x300px.jpg" alt="" style="margin:5px;width:250px;height:250px" />Important to do one´s homework</strong><br />“As a researcher, it is important not to limit your mind. One prerequisite is that you have done your homework and have a solid and stable knowledge base founded in basic theory”, Mats emphasises. “That gives you qualifications to take responsibility for development in society.”<br /><br />&quot;In order to implement your ideas, as an engineer, you can´t ignore what is possible to put into practice and what is commercially viable”, he states. “It is important to understand how your own research fits into the big picture.”<br /><br />He sees the conformity within academia as a problem.<br /><br />”People of the same type tend to choose the same type of solutions. The question is then if the right solutions really are highlighted? At Uppsala University, women account for about 40 percent in the field of electrical engineering. Perhaps I have some lessons learnt, that I could bring here”, Mats Leijon concludes.<br /><br />Text: Yvonne Jonsson<br /><br /><strong>Contact: </strong><a href="/en/Staff/Pages/Mats-Leijon.aspx">Mats Leijon</a>, Professor, Department of Electrical Engineering, Chalmers Fri, 16 Feb 2018 08:30:00 +0100 for new paradigm in pulping technology<p><b>​The Arne Asplund Mechanical Pulping Award 2018 has been granted to Professor Anders Karlström, Head of the department Electrical Engineering at Chalmers.</b></p>​The award is given out every two years by Arne Asplund Mechanical Pulping Award Foundation to promote the development of new technology for the manufacture of high-yield pulp. It is awarded in recognition of outstanding achievement in research and development of mechanical pulping technology.<br /><br /><span>“To receive this award is a great honor for me”, Anders Karlström says. “I have been working with this for many years and it feels fantastic to get a confirmation that the struggle really has been worthwhile.”<span style="display:inline-block"></span></span><br /><br />The justification for the award reads as follows: “Based on his deep understanding of the fundamentals of refining in mechanical and chemimechanical pulping, Anders Karlström has initiated a paradigm shift regarding the theory of refining by introducing the entropy model. This new approach offers tools to understand the interplay in the refining zone with regards to refiner operation, plate patterns and the produced pulp quality. These new findings are already in use in several production lines offering a set of possible ways to optimise quality and specific energy input.”<br /><br />The award consists of a gold medal and an honorarium of SEK 25,000. The prize ceremony will take place at the International Mechanical Pulping Conference, IMPC, in Trondheim on 29 May. <br /><br />Regarded as the &quot;Nobel Prize&quot; in the field of mechanical pulping, the Arne Asplund Mechanical Pulping Award was established in 1985 to commemorate the Swedish engineer Arne Asplund’s contribution to the pulp and paper industry worldwide. He was the inventor of the thermomechanical pulping technique, known as the defibrator-method, also called the Asplund-method, for pulping wooden chips.<br /><br /><a href="" target="_blank"><img class="ms-asset-icon ms-rtePosition-4" src="/_layouts/images/icgen.gif" alt="" />Read the press release</a><br /><br /><strong>Contact:</strong> <a href="/en/Staff/Pages/anders-karlstrom.aspx">Anders Karlström</a>, Professor and Head of the Department Electrical Engineering, Chalmers<br />Thu, 15 Feb 2018 13:00:00 +0100 charge of the largest battery research network in Europe<p><b>​​Patrik Johansson, Professor at the Department of Physics at Chalmers, has been elected new co-director of a large European battery research network – Alistore European Research Institute (Alistore-ERI).</b></p><img src="/SiteCollectionImages/Institutioner/F/Blandade%20dimensioner%20inne%20i%20artikel/Patrik_Johansson200x270.jpg" class="chalmersPosition-FloatRight" alt="" style="margin:5px" />The network is the largest academic-industrial collaboration on batteries in Europe and aims to tackle battery challenges and move towards sustainable energy solutions. The network has about 25 partners, with academic entities such as Cambridge, Oxford and Collège de France, and Bosch, Saft,  BASF and Renault on the industry side.<p></p> “Due to the current electromobility (r)evolution and the need to efficiently store renewable energy, Alistore-ERI is more important than ever before. As researchers, we create projects and share ideas within the network and get important feedback from other academics and the industrial partners,” says Patrik Johansson, who takes part in several national and international projects to develop the next generation of batteries.<p></p> Patrik Johansson will mainly be responsible for strategies for expansion of the network, to increase the internal and external interactions, as well as taking part in defining the research strategy. <p></p> “My role will be to build an even stronger network for future challenges – an inspiring task with many openings for Swedish industry as well,” says Patrik Johansson. <p></p> He will officially start his new assignment on 1st of January and will share the direction with Prof. Christian Masquelier from France and Dr. Robert Dominko from Slovenia. <p></p> Text: Mia Halleröd Palmgren, <a href=""></a><br /><br /><a href=""><img class="ms-asset-icon ms-rtePosition-4" src="/_layouts/images/icgen.gif" alt="" />Read more about Alistore-European Research Institute (Alistore-ERI).</a><br /><a href="/en/Staff/Pages/Patrik-Johansson0603-6580.aspx"><img class="ms-asset-icon ms-rtePosition-4" src="/_layouts/images/ichtm.gif" alt="" />Read more about Patrik Johansson and his research at Chalmers University of Technology.</a><br />Thu, 14 Dec 2017 00:00:00 +0100 scientists in sustainable energy gathers at Chalmers<p><b>​On 6-8 December, the Sustainable Energy Symposium is held at Chalmers, in collaboration with the Molecular Frontiers. The seminar brings together world-leading researchers from several science disciplines to present the latest advances within the field.</b></p>​ <br />The conference gathers distinguished researchers, industry representatives, decision makers and an engaged public for presentations and discussions on future energy solutions. Development of sustainable technologies for solar energy, batteries and energy storage is needed to make the necessary switch from fossil fuels to renewable energy sources. During the conference, the latest advances in the field will be highlighted, and the content will be made available to the public. Through live broadcast at <a href="" target="_blank">Molecular Frontiers YouTube Channel</a>  you will be able to follow the conference even if you are not in place. <br /><br /><br /><strong>150 high school students participate</strong><br />Sustainable Energy Symposium is a unique event in several ways – about half of the conference participants are high school students. This is possible thanks to the Molecular Frontiers Foundation which offers a scholarship for students from all over the country to come. The Molecular Frontiers emphasize in particular the importance of being curious and asking good questions. Approximately 150 students from all over the country are given the opportunity to listen to and ask questions to world-leading researchers.<br /><br /><br />Among the speakers are noted:<br /><br /><strong>Steven Chu, Nobel Prize winner in Physics 1997 and Obama's Energy Ministers 2009-2013.</strong><br />Steven Chu was awarded the Nobel Prize in Physics in 1997 for his work on laser cooling of atoms. Since then, his research has increasingly been about solving the challenges of climate change and sustainable energy supply. In 2009, Barack Obama appointed him the United States Secretary of Energy, and became the first scientist in an American government. After his time as Energy Secretary, he returned to research but remains a prominent debater focusing on renewable energy and nuclear power. He emphasizes the importance of reducing fossil fuel use to address global warming and climate change. He has put forward a number of innovative and sometimes controversial proposals for action.<br /><br /><strong>Paul Alivisatos, University of California at Berkeley</strong><br />Paul Alivisatos is a pioneer in nanotechnology, focusing on inorganic nanocrystals. By controlling the size and surface of the nanocrystals, his research team can tailor their properties and produce materials for a variety of applications, including solar cells and materials to reduce carbon dioxide into hydrocarbons. He has developed quantum dots, small semiconductors that are isolated from the environment and are extremely effective in absorbing and transmitting light. These are already used in the most energy efficient and high quality television screens in market today.<br /><br /><strong>Daniel Nocera, Harvard University</strong><br />Two inventions of Daniel Nocera may be of great importance in the future. The artificial leaf, mentioned in Time magazine’s list of Inventions of the Year 2011, mimics the photosynthesis, and splits water into hydrogen and oxygen by using sunlight. A further development of the concept is the bionic leaf, which takes carbon dioxide from the air and combines it with hydrogen from the artificial leaf to produce biomass and liquid fuel. In this way, a cycle is achieved that is much more efficient than photosynthesis in nature, which can contribute to a green and cheap production of fuel and food.<br /><br /><br /><strong>Program</strong><br /><a href="/en/conference/sustainableenergy/Documents/Program_Sustainable_Energy.pdf" target="_blank">Here you will find the entire program for the conference &gt;</a><br /><br /><br />Plenary lectures 7-8 December:<br />• <strong>Steven Chu</strong> – <em>Climate Change and innovative paths to a sustainable future</em><br />Nobel laureate in Physics 1997, former United States Secretary of Energy. Stanford University, United States<br />• <strong>Dame Julia King</strong> – <em>Electric vehicles in a sustainable energy system</em><br />The Baroness Brown of Cambridge DBE <br />• <strong>Sir Richard Friend</strong> – <em>How can molecules function as semiconductors?</em><br />University of Cambridge, United Kingdom<br />• <strong>Daniel G. Nocera</strong> – <em>Fuels and Food from Sunlight, Air and Water</em><br />Harvard University, United States<br />• <strong>Paul Alivisatos</strong> – <em>Quantum Dot Light Emitters: from displays to enabling a new generation of energy conversion systems</em><br />University of California, Berkeley, United States<br />• <strong>Josef Michl</strong> – <em>Singlet Fission for Solar Cells</em><br />University of Colorado Boulder, United States and Institute of Organic Chemistry and Biochemistry Academy of Sciences of the Czech Republic, Czech Republic <br />• <strong>Katherine Richardson</strong> – <em>How do we transition an entire country’s energy system to renewables?</em><br />University of Copenhagen, Denmark<br />• <strong>Harry Atwater</strong> – <em>Fuelling Human Progress with Sunlight</em><br />California Institute of Technology, United States<br />• <strong>Susanne Siebentritt</strong> – <em>Thin film solar cells – achievements and challenges</em><br />University of Luxembourg, Luxembourg<br />•<strong> Jean-Marie Tarascon</strong> – <em>Materials science for electrochemical storage: Achievements and new directions</em><br />Collège de France, FranceMon, 04 Dec 2017 11:00:00 +0100 coordinator for Sustainable Vehicle Technologies<p><b>​She does research on tomorrow’s fuels and believes that we need to change our view on transportation. Selma Brynolf is the new coordinator for the profile Sustainable Vehicle Technologies in Chalmers Areas of Advance Transport and Energy.</b></p>​“It's an exciting assignment and I look forward to learning more about the research on transport and sustainable vehicles that is conducted at Chalmers and University of Gothenburg.”<br /><br />As post-doc at the department of Space, Earth and Environment at Chalmers, Selma Brynolf has evaluated the environmental impact of marine fuels from a lifecycle perspective and worked with modeling of energy systems. Since October 2017, she will also coordinate Sustainable Vehicle Technologies, a profile shared between the Areas of Advance Transport and Energy. She will work together with Anders Nordelöf, who continues his assignment as vice coordinator.<br /><br />“I currently work with two main questions”, says Selma Brynolf. “Evaluation of possible future fuels and propulsion technologies for shipping, as well as the role that fuels produced from carbon dioxide and water using electricity could have in the transport sector.<br /><br />Maria Grahn, previous coordinator of Sustainable Vehicle Technologies, is now director of Chalmers Energy Area of Advance.<br /><br />“I am pleased and proud to announce a new, strong leadership for Sustainable Vehicle Technologies. Handing over to Selma Brynolf and Anders Nordelöf feels very good, I am certain that the work will be continued in the best possible way.”<br /><br />Selma points out that an important and challenging part of her research is to find sustainable solutions for all modes of transport. She believes that electrification is a possibility for many parts of the transport sector, not just for cars, and that it is very exciting to follow the development.<br /><br />“But there are many more areas that need to be developed. I also believe that we need to think again and change our view of transport in general and the benefit they give us. I hope to contribute to a slightly more sustainable transport sector.”<br /><br />Text: Julia Jansson och Emilia Lundgren<br />Fri, 03 Nov 2017 10:05:00 +0100 research opportunities for Chalmers researchers as ElectriCity grows<p><b>​ElectriCity, best known for the electric bus 55 in Gothenburg, is much more than just the bus. As the project grows, new exciting opportunities for research appear. Per Lövsund, coordinator for ElectriCity at Chalmers University of Technology, invites Chalmers researchers to contact him with ideas.</b></p><p><br /></p> <p>“We can perform research projects, master and bachelor thesis projects within ElectriCity, and thereby gain better dissemination and utilisation of our results”, says Per Lövsund, who calls on Chalmers researchers to contact him with ideas for new projects.<br /></p> <p><br /></p> <p>ElectriCity is now growing to include for example smaller trucks, such as waste trucks and distribution cars. This means exciting opportunities for several research areas, Per Lövsund explains. Self-driving vehicles, safety, community planning, noise, thermal optimization, control algorithms, vehicle dynamics, development and recycling of batteries and fuel cells, and charging station requirements are some examples of questions from different research fields, all of which can be studied within the framework of ElectriCity.<br /></p> <p><br /></p> <p>Researchers involved in ElectriCity have access to research platforms such as buses and other vehicles. The project’s demo arena also includes the new urban area Frihamnen and the development of south Chalmers Johanneberg Campus, with a stop for the ElectriCity bus. Here, safety aspects and new innovative solutions at the stop and interactions between vehicles and unprotected road users can be studied.<br /></p> <p><br /></p> <p>The fact that ElectriCity enters a new phase has already generated new research at Chalmers.<br /></p> <p><br /></p> <p>“One project about bus trains and one about autonomous docking at bus stops are just about to take off”, says Per Lövsund. “Another project investigates how bus drivers experience the effects of the Volvo Dynamic Steering system.”<br /></p> <p><br /></p> <p>A workshop is planned to be held at Chalmers to formulate projects on low-frequency noise in urban environment, modeling of noise impact and safety issues regarding quiet buses at bus stops.<br /></p> <p><br /></p> <p>“In the long run, perhaps other sectors could be included as well. I personally think that the marine sector would be interesting”, says Per Lövsund. “Chalmers has great competence in this field, for example through <a href="">SSPA </a>and <a href="">Lighthouse</a>.” <br /></p> <p><br /></p> <p>ElectriCity has run in Gothenburg for two years and is a collaboration between industry, academia and society, where the participants develop and test solutions for tomorrow’s sustainable public transport. The electric and hybrid buses of route 55, where different technology solutions are tested and developed, run between the two campuses of Chalmers. The project has created a lot of international interest.<br /></p> <p><br /></p> <p>“The international attention has given us new networks and new interesting research topics”, concludes Per Lövsund.</p> <p><br /></p> <p>Are you a Chalmers researcher and have a project idea for ElectriCity? Contact Chalmers coordinator Per Lövsund, <a href=""></a><br /></p> <p><br /></p> <p><a href="">Read more about ElectriCity &gt;&gt;</a><br /><br /></p> <p><br /></p> <p><em>Text: Christian Boström, Emilia Lundgren</em><br /></p>Mon, 23 Oct 2017 00:00:00 +0200 gamma rays that will reach beyond the limits of light<p><b>​Researchers have discovered a new way to produce high energy photon beams. The new method makes it possible to produce these gamma rays in a highly efficient way, compared with today’s technique. The obtained energy is a billion times higher than the energy of photons in visible light. These high intensity gamma rays significantly exceed all known limits and pave the way towards new fundamental studies.</b></p><p></p> <img width="120" height="156" class="chalmersPosition-FloatRight" alt="arkady140x182.jpg" src="/en/departments/physics/news/Documents/arkady140x182.jpg" style="margin:5px" />“When we exceed the limit of what is currently possible, we can see deeper into the basic elements of nature. We can dive into the deepest part of the atomic nuclei,” says Arkady Gonoskov, researcher at the Department of Physics at Chalmers University of Technology. <p></p> <p></p> The results were recently published in the high impact journal Physical Review X. The new method is an outcome of a collaboration between Chalmers University of Technology, Institute of Applied Physics and Lobachevsky University in Russia and University of Plymouth in the UK. Physicists in different fields, as well as computer scientists, have managed to work out the numerical models and analytic estimates for simulating these ultra-strong gamma rays in a new and somehow unexpected way. <p></p> In normal cases, if you shoot a laser pulse at an object, all the particles scatter. But if the laser light is intense enough and all parameters are right, the researchers have found that the particles are instead trapped. They form a cloud where particles of matter and antimatter are created and start to behave in a very special, unusual way. <p></p> <p></p> <span><img width="120" height="155" class="chalmersPosition-FloatRight" src="/SiteCollectionImages/Institutioner/F/Divisions/Condensed%20Matter%20Theory/Staff/Mattias-Marklund.png" alt="" style="margin:5px" /><span style="display:inline-block"></span></span>“The cloud of trapped particles efficiently converts the laser energy into cascades of high energy photons – a phenomena that is very fortunate. It’s an amazing thing that the photons from this source can be of such high energy,” says Mattias Marklund, professor at the Department of Physics at Chalmers. <p></p> The discovery is highly relevant for the future large scale laser facilities that are under development right now. The most intense light source on earth will be produced at such research facilities – as big as football fields. <p></p> “Our concept is already part of the experimental program proposed for one such facility: Exawatt Center for Extreme Light Studies (XCELS) in Russia. We still don’t know where these studies will lead us, but we know that there are yet things to be discovered within nuclear physics, for example new sources of energy. With fundamental studies, you can aim at something and end up discovering something completely different – which is more interesting and important,” says Arkady Gonoskov. <p></p> Text: Mia Halleröd Palmgren, <a href=""></a><p></p> <a href=""><img class="ms-asset-icon ms-rtePosition-4" src="/_layouts/images/icgen.gif" alt="" /></a>​ <strong>Read the scientific article</strong> <a href="">Ultrabright GeV Photon Source via Controlled Electromagnetic Cascades in Laser-Dipole Waves</a> in Physical Review X.<p></p> <p><a href=""><img class="ms-asset-icon ms-rtePosition-4" src="/_layouts/images/icgen.gif" alt="" />Read the press release and download high-resolution images. ​</a></p> <h5 class="chalmersElement-H5">More information: </h5> <p></p> <a href="/sv/personal/Sidor/Mattias-Marklund.aspx">Mattias Marklund</a>, Professor, Department of Physics, Chalmers University of Technology, +46 31 772 39 39, <p></p> <p></p> <a href="/en/staff/Pages/arkady-gonoskov.aspx">Arkady Gonoskov</a>, researcher, Department of Physics, Chalmers University of Technology, +46 31 772 62 89,  <p></p> <strong>Further reading:</strong> <a href="/en/departments/physics/news/Pages/The-code-behind-a-breakthrough.aspx">The code behind a breakthrough in plasma physics.</a><p>​ </p>Thu, 19 Oct 2017 08:00:00 +0200 cars can become more eco-friendly through life cycle assessment<p><b>​It is time to stop discussing whether electric cars are good or bad. Instead industry, authorities and policy-makers need to work together to make them as eco-friendly as possible. This is the view taken by Anders Nordelöf, a researcher at Chalmers University of Technology. In a recent thesis, he provides concrete advice and tools showing how life cycle assessment can assist in the development of electric cars.</b></p><div>​Electric cars have been criticised in recent times due to their energy-intensive manufacturing processes and because they are currently charged using electricity which is partly produced from fossil fuels.</div> <div> </div> <div> </div> <div> </div> <div>Anders Nordelöf, a researcher in environmental systems analysis at Chalmers University of Technology, is seeking a more future-oriented approach to the electric car. He thinks it is necessary to focus on solving the problems that arise in the transition to the new technology.</div> <div> </div> <div> </div> <div> </div> <div>“We need to take the environmental problems with electric cars seriously, but we mustn’t get caught up in the situation as it now stands. It’s time to give up discussing whether the electric cars of today are good or bad, and start working together step-by-step to make them as good as possible from an environmental perspective,” he says.</div> <div> </div> <div> </div> <div> </div> <div>“Comparing electric cars with diesel or petrol driven vehicles is relevant, but not the most important issue – nor is it what will solve the problems in the long term. We know that fossil fuels have to be phased out, and the automotive industry has decided upon electrification. The most important thing then is to find the best way forward.”</div> <div> </div> <div> </div> <div> </div> <div>Nordelöf points out that the great strength of the electric car is in its potential. In a recent thesis he gives clear advice to industry, policy-makers and authorities to work together to develop electric cars by making their production as fossil-free as possible.</div> <div> </div> <div> </div> <div> </div> <div><div>“If we charge the car from a clean source of electricity and combine this with the lowest possible carbon dioxide emissions during production, then the electric car will be revolutionary. But we can’t expect to find a ready-made solution immediately,” he says.</div> <div> </div> <div><img src="/sv/institutioner/tme/PublishingImages/Nyheter/Andra%20storlekar/Andreasiwebbtext.jpg" alt="" style="margin:5px" /> </div> <h4 class="chalmersElement-H4" style="text-align:center"><span>&quot;<span></span><span></span></span><span><span>The electric car has the potential to become revolutionary. But we can’t expect to find a ready-made solution immediately<span style="display:inline-block"></span></span>&quot;<span></span></span><span><span></span></span></h4> <h6 class="chalmersElement-H6" style="text-align:center"><span><span>Anders Nordelöf, Chalmers</span></span></h6></div> <div> </div> <div> </div> <div> </div> <div>He is providing key pieces of the puzzle to help progress the development of electric cars, and shows in his thesis how life cycle assessment, LCA, can be used to minimise their environmental impact in the long term. </div> <div> </div> <div> </div> <div> </div> <div>The thesis contains details of specific tools, methodology recommendations and new models for collecting LCA data, which are aimed at anyone working on the development of electric-powered vehicles using life cycle assessment.</div> <div> </div> <div> </div> <div> </div> <div>“The models fill important data gaps and allow relevant LCA studies to be carried out on electric powertrains. These studies can then be applied to many different types of vehicles. I’ve also compared the overall environmental impact from three different electric motors, and can therefore provide basic advice on how to design electric motors to produce as little environmental impact as possible,” he says.</div> <div> </div> <div> </div> <div> </div> <div>Nordelöf provides some technology advice for the automotive industry based on his research. He stresses that energy efficiency and greater production of electricity from renewables is the key to reducing the environmental impact of electric cars in the operational phase, globally.</div> <div> </div> <div> </div> <div> </div> <div>“But it’s also important to realise that the manufacture of components will make up an ever greater proportion of the electric car’s environmental impact the further our developments progress, especially if you take a broader perspective than just greenhouse gases. There are major environmental challenges in the extraction of metals, placing many requirements on the supply chain,” he says.</div> <div> </div> <div> </div> <div> </div> <div>Nordelöf’s study also contains a summary of what previous LCA studies had to say about the environmental impact of electric cars. He points out that the results are contradictory and disparate, while showing that this is mainly due to shortcomings in the design and reporting of the studies – since the choice of methodology, purpose and target group are not clearly presented. </div> <div> </div> <div> </div> <div> </div> <div>“More rigorous reporting is required in the research field so as not to increase the confusion that already exists around the environmental impact of electric cars,” he says.</div> <div> </div> <div> </div> <div><strong> </strong></div> <strong> </strong><div><strong>Text and photo: Ulrika Ernström</strong><br /><br /></div> <div> </div> <div></div> <div> </div> <h4 class="chalmersElement-H4"><span></span>FACTS, RESEARCH<span></span><span></span> AND MORE INFORMATION:<span><span></span></span></h4> <div> </div> <div><a id="20171011"><span class="ms-offscreen">Octobe</span></a><a id="20171011"><span class="ms-offscreen"></span></a></div> <div> </div> <div><strong>Life cycle assessment (LCA)</strong> is a systems method that provides a holistic overview of a product’s environmental impact over its life cycle from raw material extraction, through production processes and use, to waste management, including all transportation and energy consumption in the intermediate stages.</div> <div> </div> <div> </div> <div> </div> <div><a href="">Read Nordelöf’s thesis:<span></span><span style="display:inline-block"></span></a> Using life cycle assessment to support the development of electrified road vehicles. Component data models, methodology recommendations and technology advice for minimizing environmental impact.<br /><br /><a href="/sv/personal/Sidor/anders-nordelof.aspx">Read more about Anders Nordelöf</a></div> <div> </div> <div> </div> <h4 class="chalmersElement-H4"><span></span><span></span><span></span><span></span></h4> <h4 class="chalmersElement-H4"> <span></span><span></span><span></span><span></span><span></span><span></span></h4>Wed, 11 Oct 2017 00:45:00 +0200 Kåberger senor advisor for GEIDCO<p><b>​Tomas Kåberger has been appointed Senior Advisor to Global Energy Interconnection Development and Cooperation Organisation, GEIDCO, an organisation dedicated to promoting the sustainable development of energy worldwide.</b></p><img src="/SiteCollectionImages/Institutioner/SEE/Profilbilder/Tomas_Kaberger170x220_1.jpg" class="chalmersPosition-FloatRight" alt="" style="margin:5px" />– It’s a great constructive assignment, in an organization that has real possibilities to influence the world, says Tomas Kåberger, P​rofessor of Industrial Energy Policy, at Chalmers University of Technology.  <br /><span style="background-color:initial"></span><div><br /></div> <div><span></span><div><span style="background-color:initial">The organisation is lead by Chairman Zhenya Liu, former head of the world’s largest electricity company State Grid Corporation of China, and with the former US Secretary of Energy, and Nobel Laureate, Stephen Chu as vice chairman. </span></div> <div><span style="background-color:initial"><br /></span></div> <div><span style="background-color:initial">​GEIDCO </span><span style="background-color:initial">has the ambition to combine renewable energy, smart grid technologies and ultra-high voltage transmission </span><span style="background-color:initial">technologies to create global renewable energy supply. </span><span style="background-color:initial">It is to be achieved with “two replacements, one restore, and one increase”. Renewable energy shall replace fossil fuels for electricity production, renewable electricity is to replace fossil fuels in other sectors, oil is to restored as a raw-material, and electricity use is to increase.</span></div> <div><br /></div></div> <div><a href="">Read more att</a>. </div> ​Tue, 03 Oct 2017 10:00:00 +0200 on Digitalised Electricity Networks<p><b>​A new cross-disciplinary research project targets the next generation technologies for electricity distribution. The 3,5 year United-Grid project is funded by EU Horizon2020.</b></p>​ <br />The electricity market of today faces unprecedented complexity caused by new distributed market actors along with emerging technologies such as renewable generation, energy storage, and demand resources. The United-Grid project aims to secure and optimize operation of the future intelligent distribution networks needed to handle the increasing complexity.<br /><br />The EU Horizon2020 project runs from November 2017 to April 2021 and the consortium consists of eleven partners from France, The Netherlands, and Sweden. The research team from Chalmers is cross-disciplinary and include Tuan Le, David Steen from the department of Electrical Engineering, and Magnus Almgren, Marina Papatriantafilou, Vincenzo Massimiliano Gulisano from the department of Computer Science and Engineering.<br /><br />The core deliverable is the United-Grid tool-box that could be “plugged in” to the existing Distribution Management System (DMS) via a cross-platform for energy management, grid-level control and protection. The Computer Science and Engineering work in the project is about security perspectives in the distributed infrastructure, in which the data-stream processing methods are catalytic for addressing detection possibilities.<br /><br />United-Grid was prepared in response to the Horizon2020 work program “LCE-01-2016-2017: Next generation innovative technologies enabling smart grids, storage and energy system integration with increasing share of renewables: distribution network”. <br /><br />Contact: <br />Project coordinator, <a href="/en/Staff/Pages/anh-tuan-le.aspx">Tuan Le</a>, Electrical Power Engineering, department of Electrical Engineering<br />Project administrator, <a href="/en/staff/Pages/jacqueline-plette.aspx">Jacqueline Plette</a>, Chalmers Operative and Strategic Support<br />Thu, 28 Sep 2017 09:00:00 +0200 is becoming a unique marketplace for energy<p><b>​Campus Johanneberg is becoming a test arena for the local energy supply of the future. A cloud-based trading venue will control the production and use of electricity, heat and cooling in the buildings around the clock. The conclusions will be utilized by cities in the EU that want to develop into fossil-free communities.</b></p><div>​The project is quite unique in taking a holistic approach to all energy supplies – from electricity to heating and cooling. By way of a customized digital marketplace, the energy system will balance supply and demand for energy, depending on a variety of parameters. Nine partners, led by the city of Gothenburg, are engaged in the project (see facts below).</div> <div> </div> <div><span>A group of researchers at Chalmers have done simulations and analysis during the spring and summer to build the models that will make the energy system and the marketplace work.<span style="display:inline-block"></span></span></div> <div><img src="/SiteCollectionImages/Institutioner/E2/Nyheter/Chalmers%20blir%20unik%20handelsplats%20för%20energi/FED-forskare-DSC_6660_600px.jpg" class="chalmersPosition-FloatLeft" alt="" style="margin:5px" /></div> <div> </div> <div> </div> <div> </div> <div> </div> <div> </div> <div> </div> <div> </div> <div> </div> <div> </div> <div> </div> <div> </div> <div> </div> <div> </div> <div> </div> <div> </div> <div> </div> <div> </div> <div> </div> <div><em><br /></em></div> <div><em>Anh Tuan Le, Kalid Yunus, Zack Norwood and David Steen, researchers at the division of Electric Power Engineering, are contributing with simulations and analysis for the energy system and the cloud-based marketplace at campus Johanneberg. </em></div> <div> </div> <div>&quot;We have developed an investment model that prescribes technical solutions to reach the goals to reduce energy consumption and cut energy peaks at the campus area,&quot; says David Steen, researcher at the Department of Electrical Engineering. &quot;It also shows how the system should be operated by combining different energy sources, depending on what is most beneficial in terms of environment and economy, at any given time.&quot;</div> <div> </div> <div><strong>Takes care o</strong><span><span><span><span><img src="/SiteCollectionImages/Institutioner/E2/Nyheter/Chalmers%20blir%20unik%20handelsplats%20för%20energi/David_Steen_150px.jpg" class="chalmersPosition-FloatLeft" alt="" style="margin:5px" /></span></span></span></span><strong>f excess energy</strong></div> <div>&quot;Electricity, heat and cooling produced at Chalmers can be stored and transferred between the buildings. Thus, we can <span><span><span></span></span></span>use excess energy and keep down the amount of electricity that needs to be generated locally or purchased fro<span><span></span></span>m outside&quot;, says David. &quot;To a large extent, campus already is self-sufficient in terms of district heating, thanks to Kraftcentralen – Chalmers' own combined heat and power plant (CHP).&quot;</div> <div><br /></div> <div><br /></div> <div><br /></div> <div><span><em><br /></em></span></div> <div><span><em>David Steen, researcher in Electric Power Engineering</em></span><span id="ms-rterangepaste-end" style="display:inline-block"><br /></span></div> <div><br /></div> <div>The researchers recommend a combination of different production techniques and energy storage, such as combined heat and power plant, solar panels, heat pumps, absorption chillers, batteries and thermal storage. Some of this already exists on campus today, but a good deal remains to be built in the coming year. In September, investment decisions with a budget of 15 million will be made.</div> <div> </div> <div>The new energy system will also benefit from investments that the property manager Akademiska Hus is planning, in addition to the FED project plans.</div> <div> </div> <div><strong>Free trading in the campus area</strong></div> <div>When it comes to how electricity can be traded in a local area, the project is also innovative. Thanks to the fact that many of the buildings in the campus area included in the project are exempted from the Swedish legal requirements for network concessions, different players can sell and buy electricity among themselves without restrictions. This is a prerequisite for testing the local energy market.</div> <div> </div> <div>In what ways will the students and those working and visiting Chalmers notice the test arena?</div> <div>&quot;Hopefully not at all&quot;, says David. &quot;The indoor climate in the premises should not be affected and the system will be self-governing. On the other hand, one may notice such things as the building of a 280-cubic meter accumulator tank at Kraftcentralen and installations of solar cells on the roofs. We also hope that interested students want to engage in different ways. Among other things, students will be invited to take part in innovation competitions and there is also the opportunity to complete both master thesis and bachelor projects linked to the project.&quot;</div> <div> </div> <div>A showroom will be established on campus, where the project will be displayed to interested visitors.</div> <div> </div> <div><strong>Full operation by the end of 2018</strong></div> <div>The researchers will continue to refine and complete the model through 2018. For example, forecasts for energy use will be included, as well as any restrictions affecting the transmission possibilities.</div> <div> </div> <div>“Our project partner Akademiska Hus is already working actively to reduce energy consumption in the premises. Therefore, it will be an additional challenge for us to reach the goal of reducing energy imports by as much as 30 percent,&quot; says David.</div> <div> </div> <div>This autumn, construction work will start on campus and in December 2017, the first version of the energy marketplace will be launched. From autumn 2018, everything is planned to be fully operational and after one year of operation, conclusions will be drawn, useful for EU cities wanting to implement the system on a larger scale.</div> <div> </div> <div><strong>Continued research on the future energy system</strong></div> <div>“It's really an exciting project to work in”, says David. “We all contribute with different competences in the cooperation. In addition, it gives us the opportunity to continue our research about local energy systems and to further develop the models we have created. Small local energy systems will be increasingly important for fossil-free and renewable energy supply in the future. There is an increasing interest in this, which benefits the society and also means a profitable development for different types of property owners.</div> <div><br /></div> <div><img src="/SiteCollectionImages/Institutioner/E2/Nyheter/Chalmers%20blir%20unik%20handelsplats%20för%20energi/FED-forskare-DSC_6669_340px.jpg" class="chalmersPosition-FloatLeft" alt="" style="margin:5px" /></div> <div><br /></div> <div><br /></div> <div><br /></div> <div><br /></div> <div><br /></div> <div><br /></div> <div><br /></div> <div><br /></div> <div><br /></div> <div><br /></div> <div><br /></div> <div><br /></div> <div><br /></div> <div><br /><em>Small local energy systems will be increasingly important for fossil-free and renewable energy supply in the future, according to </em><span><em> Kalid Yunus<span style="display:inline-block">,  </span></em></span><em>Anh Tuan Le, Zack Norwood and David Steen, Chalmers</em><span>'<span style="display:inline-block"></span></span><em> researchers in the FED-project.<br /></em></div> <div><br /><em></em></div> <div><strong>Text and photo:</strong> Yvonne Jonsson<br /> </div> <div><br /></div> <div><br /></div> <div><strong>Some objectives for the project</strong></div> <ul><li>Reduce the import of energy to the campus area by 30 percent</li> <li>Cut the energy peaks, when fossil energy is used, by 80 percent</li> <li>10 000 transactions on the local energy market</li></ul> <div> </div> <div> </div> <div><strong>About the project</strong></div> <div>The Fossil-free Energy Districts project, FED, is an innovative effort by the City of Gothenburg, Sweden, to decrease the use of energy and the dependence on fossil fuel in a built environment. A unique local market for electricity, district heating and cooling is being developed together with eight strong partners. Johanneberg Science Park, Göteborg Energi, Business Region Göteborg, Ericsson, RISE Research Institutes of Sweden, Akademiska Hus, Chalmersfastigheter and Chalmers University of Technology are all contributing with their expertise and knowledge to make FED attractive for other European cities as well. During 2017−2019 the FED testbed will be situated on Campus Johanneberg. FED is co-financed by the European Regional and Development Fund through the Urban Innovative Actions Initiative, an initiative of the European Commission for cities to test new solutions for urban challenges.</div> <div><br /></div> <a href="" target="_blank"><div>Read more about FED at the homepage for UIA</div></a><div><br /></div>Wed, 27 Sep 2017 09:00:00 +0200 director of the Energy Area of Advance<p><b>​The Energy Area of Advance welcomes Maria Grahn as the new director. She will be replacing Mats Rydehell the 1 October 2017.</b></p>Maria Grahn is today a part of the profile area management for Sustainable Vehicle Technologies - one of six profile areas within Chalmers Energy Area of Advance.<br /><br />– It is with great excitement that I look forward to leading the Energy Area of Advance, says Maria Grahn. A global shift in the energy system aiming at lower emission of greenhouse gas is a key element in reaching the ambitious climate goals. Sweden aims at being one of the first welfare nations in the world boasting zero net emission of greenhouse gas. This means that there are huge energy related societal challenges for the Area of Advance to take on and collaboration is a key term. <br /><br />Maria was recently acknowledged for her research collaboration with Karin Andersson, focusing on the future of the shipping industry. They received the 2017 Areas of Advance Award.<br /><br />Maria Grahn's research at the department of Space, Earth and Environment is within the area of energy systems analysis, focusing on fuels for transport, global energy systems modeling, cost-effective use of biomass, global warming and carbon dioxide reductions. Maria is also interested in the global car fleet, the role of Electrofuels (fuels produced from carbon dioxide and water with the help of electricity) and in future fuels for the shipping industry. <br />Mon, 25 Sep 2017 12:00:00 +0200’s-one-year-anniversary.aspx house for the celebration of HSB Living Lab’s one-year anniversary<p><b>​When HSB Living Lab celebrated its first anniversary it was attended by representatives of Chalmers, HSB and Johanneberg Science Park as well as the Government and the City of Gothenburg.</b></p>​  “We at the Ministry for Enterprise and Innovation are pushing to try to obtain more test beds where we can use new technology, and HSB Living Lab is a really good example of that,” said Minister for Housing and Digital Development <strong>Peter Eriksson</strong> (MP) during his speech at HSB Living Lab.<br /><br />HSB Living Lab is a unique research arena situated in the Chalmers area in Gothenburg. One complete outfit specialising in finding sustainable living solutions for the future. Those living in the 29 apartments have now been a part of the innovation project for a year - a project which constitutes cooperation between trade and industry, city and academia. 2000 sensors spend 24 hours a day collecting data which can be used to find new living solutions for the future.<br /><br />The 1-year anniversary was celebrated on Tuesday September 19. The visit began at <span><span></span><span> Johanneberg Science Park <span style="display:inline-block"></span></span></span>with a presentation of some ongoing research projects <span><span style="display:inline-block"></span></span>which are linked to the HSB Living Lab building and to Chalmers. Presentations included building-integrated solar panels, city simulations and research into how much reconstruction goes on within the apartments. <br /><br />During his welcome, MD of HSB Gothenburg <strong>Lars Göran Andersson l</strong>ed three cheers for HSB Living Lab.<br />   “We now have another nine years of research to go,” he said, indicating that HSB Living is a ten-year project.<br /><br /><img src="/en/areas-of-advance/buildingfutures/news/Documents/HSB_LivingLab1ar_170919_2.jpg" alt="HSB_LivingLab1ar_170919_2.jpg" style="margin:5px" /><br /><br />After Peter Eriksson had been shown around the premises, a panel debate was held on the subject of “<strong><em>Smart cities, what do we mean by that</em></strong>?” where discussions concerned the challenges faced by researchers, housing companies and the politicians. The subjects of ownership, virtual town urban planning, the importance of abbreviated construction processes and smart cities and the way to get the most from the research which exists and is ongoing at HSB Living Lab were debated while many of the audience were standing all the way down to HSB Living Lab’s modern laundry.<br /><br />The moderator was <strong>Lars Marcus</strong>, Professor of Urban Design and Planning at Chalmers.<br /><br />The panel:<br /><ul><li>Peter Eriksson (MP), Minister for Housing and Digital Development</li> <li>Anders Lago, Chairperson of the HSB Association</li> <li>Anders Logg, Acting Area of Advance Director Building Futures</li> <li>Anna Dubois, Vice President of Chalmers</li> <li>Mats Bergh, MD of Johanneberg Science Park</li> <li>Ann-Sofie Hermansson (S), Chairperson of the Municipal Board</li></ul> <br />Peter Eriksson concluded the panel debate confidently.<br />   “I think it’s all about using the new opportunities provided by new technology to build a more humane society where we invest in quality of life where people will be able to socialise and think of each other with love and kindness rather than distance themselves. I believe there are enormous opportunities to be had from the technology if we use it in the right way.”<br /><br /><img src="/en/areas-of-advance/buildingfutures/news/Documents/HSB_LivingLab1ar_170919_46.jpg" alt="HSB_LivingLab1ar_170919_46.jpg" style="margin:5px" /><br /><br />The visit was jointly arranged by Chalmers, HSB and Johanneberg Science Park.<br />Tue, 19 Sep 2017 17:00:00 +0200 crucial for transitioning to a sustainable society<p><b>​How do we successfully transition to a sustainable society, as fast as the climate requires? It’s complex, and many categories need to take action – politicians, companies and researchers. They all met at the 8th International Sustainability Transitions conference at Chalmers in June 2017.</b></p>​​Nearly all the countries in the world have subscribed to the vision of a sustainable future. But how do we achieve it? What obstacles are in the way? What roles should various players have, and how do we make the transition go fast enough? <br /><br />At the 8th International Sustainability Transitions Conference, hosted by Chalmers, scientists, politicians, organisations, and industry representatives addressed these questions. Watch the video above to hear some prominent voices from the conference.<br /><br />Read more:<br /><a href="/en/areas-of-advance/energy/joint_initiatives/Pages/Chalmers-Initiative-in-Innovation-and-Sustainability-Transitions.aspx">Sustainability transitions research at Chalmers</a><br /><a href="">8th International Sustainability Transitions Conference</a><br /><br />Video: Torgil Störner and Ingela RoosThu, 22 Jun 2017 00:00:00 +0200 of runaway electrons paves the way for fusion power<p><b>​Fusion power has the potential to provide clean and safe energy that is free from carbon dioxide emissions. However, imitating the solar energy process is a difficult task to achieve. Two young plasma physicists at Chalmers University of Technology have now taken us one step closer to a functional fusion reactor. Their model could lead to better methods for decelerating the runaway electrons, which could destroy a future reactor without warning.</b></p><div>​It takes high pressure and temperatures of about 150 million degrees to get atoms to combine. As if that was not enough, runaway electrons are wreaking havoc in the fusion reactors that are currently being developed. In the promising reactor type tokamak, unwanted electric fields could jeopardise the entire process. Electrons with extremely high energy can suddenly accelerate to speeds so high that they destroy the reactor wall. <br /> <br /></div> <div><span><img src="/SiteCollectionImages/Institutioner/F/340x296px/LinneaOla340x296IMG_0991.jpg" class="chalmersPosition-FloatRight" width="272" height="237" alt="" style="margin:5px" /></span>It is these runaway electrons that doctoral students Linnea Hesslow and Ola Embréus have successfully identified and decelerated. Together with their advisor, Professor Tünde Fülöp at the Chalmers Department of Physics, they have been able to show that it is possible to effectively decelerate runaway electrons by injecting so-called heavy ions in the form of gas or pellets. For example, neon or argon can be used as “brakes”. <br /><br />When the electrons collide with the high charge in the nuclei of the ions, they encounter resistance and lose speed. The many collisions make the speed controllable and enable the fusion process to continue.  Using mathematical descriptions and plasma simulations, it is possible to predict the electrons' energy – and how it changes under different conditions. </div> <div> </div> <div>“When we can effectively decelerate runaway electrons, we are one step closer to a functional fusion reactor. Considering there are so few options for solving the world's growing energy needs in a sustainable way, fusion energy is incredibly exciting since it takes its fuel from ordinary seawater,” says Linnea Hesslow. </div> <div> </div> <div>She and her colleagues recently had their article published in the reputed journal Physical Review Letters. The results have also attracted a great deal of attention in the field of research. In a short period of time, 24-year-old Linnea Hesslow and 25-year-old Ola Embréus have given lectures at a number of international conferences, including the prestigious and long-standing <a href="">Sherwood Fusion Theory Conference in Annapolis</a>, Maryland, USA, where they were the only presenters from Europe. </div> <div> </div> <div>“The interest in this work is enormous. The knowledge is needed for future, large-scale experiments and provides hope when it comes to solving difficult problems. We expect the work to make a big impact going forward,” says Professor Tünde Fülöp. </div> <div> </div> <div>Despite the great progress made in fusion energy research over the past fifty years, there is still no commercial fusion power plant in existence. Right now, all eyes are on the international research collaboration related to <a href="">the ITER reactor in southern France.</a><br /><br /></div> <div>“Many believe it will work, but it's easier to travel to Mars than it is to achieve fusion. You could say that we are trying to harvest stars here on earth, and that can take time. It takes incredibly high temperatures, hotter than the center of the sun, for us to successfully achieve fusion here on earth. That's why I hope research is given the resources needed to solve the energy issue in time,” says Linnea Hesslow.<br /><br /></div> <div>Text and image: Mia Halleröd Palmgren, <a href=""></a></div> <div> <img src="/SiteCollectionImages/Institutioner/F/750x340/fusionsreaktor_image_EUROfusion750x340.jpg" alt="" style="margin:5px" /><br /><span>Although the vacuum chamber in the British fusion reactor JET has a wall made of solid metal, it can melt if it gets hit by a beam of runaway electrons. It is these runaway elementary particles that doctoral students Linnea Hesslow and Ola Embréus have successfully identified and decelerated.<br /></span><span>Image:  © Eurofusion<span style="display:inline-block"></span></span><span> <span style="display:inline-block"></span></span><br /></div> <h3 class="chalmersElement-H3">Facts: Fusion energy and runaway electrons <br /></h3> <div>Fusion energy occurs when light atomic nuclei are combined using high pressure and extremely high temperatures of about 150 million degrees Celsius. The energy is created the same way as in the sun, and the process can also be called hydrogen power. Fusion power is a much safer alternative than nuclear power, which is based on the splitting (fission) of heavy atoms. If something goes wrong in a fusion reactor, the entire process stops and it grows cold. Unlike with a nuclear accident, there is no risk of the surrounding environment being affected. The fuel in a fusion reactor weighs no more than a stamp, and the raw materials come from ordinary seawater. </div> <div>As yet, fusion reactors have not been able to produce more energy than they are supplied. There is also a problem with so-called runaway electrons. The most common method of preventing this damage is to inject heavy ions, such as argon or neon, which act like brakes due to their large charge. A new model developed by researchers at Chalmers describes how much the electrons are decelerated, paving the way to making these runaway electrons harmless.  <br /><br /></div> <div>Read the scientific article <a href="">“Effect of partially-screened nuclei on fast-electron dynamics&quot;</a>.<br /></div> <div>  <br /></div> <div>The article was written by Linnea Hesslow, Ola Embréus, Adam Stahl, Timothy DuBois, Sarah Newton and Tünde Fülöp of the Department of Physics at Chalmers University of Technology, and Gergely Papp of the Max Planck Institute for Plasma Physics in Garching, Germany. <br /></div> <h3 class="chalmersElement-H3">More information: <br /></h3> <div><span><a href="/en/Staff/Pages/hesslow.aspx"><strong><span><strong>Linnea Hesslow</strong></span></strong><span></span></a>,</span> PhD Student, Department of Physics, Chalmers University of Technology, +46 70 519 41 67,</div> <div><strong><a href="/en/staff/Pages/embreus.aspx">Ola Embréus</a></strong>, PhD Student, Department of Physics, Chalmers University of Technology, +46 73 052 80 70,</div> <div><strong><span><a href="/en/Staff/Pages/Tünde-Fülöp.aspx">Tünde Fülöp</a></span></strong>, Professor, Department of Physics, Chalmers University of Technology, +46 72 986 74 40,<br /><br /><a href=""><img class="ms-asset-icon ms-rtePosition-4" src="/_layouts/images/icgen.gif" alt="" />Read the press release and download high resolution images. </a><br /></div>Tue, 20 Jun 2017 00:00:00 +0200