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Stefan Östlund Electrical Engineering. 1970. 1979. 1983. 1987. 1993. 2000. 2005. A forty year perspective on the Swedish Energy System : Energy Efficiency, New Transport Patterns, Renewable Energy, Nuclear Power and Systems Thinking. 13,00. 12,00. 11,00. 10,00.
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Stefan ÖstlundElectrical Engineering KTH www.ecs.kth.se
1970 1979 1983 1987 1993 2000 2005 A forty year perspective on the Swedish Energy System: Energy Efficiency, New Transport Patterns, Renewable Energy, Nuclear Power and Systems Thinking 13,00 12,00 11,00 10,00 Ton CO2 emissions per capita and year 9,00 8,00 7,00 6,00 5,00 2009 4,00 5400 5600 5800 6000 6200 6400 6600 Average primary energy supply per capita in Watts KTH www.ecs.kth.se
Energy at KTH - today • KTH initiatives • Catalysing the development and maintenance of a meta network • Providing service and support to KTH research and external stakeholders • National initiatives • Strategic Research Area in Energy • National initiatives with industry • SKC - Swedish Centre for Nuclear Technology • Electric Power Research Centre • Centre for Efficient Refrigeration and Heat Pump Systems • … • European initiatives • A large number of EU FP 7 projects • Partner and regional lead in EIT/KIC InnoEnergy KTH www.ecs.kth.se
KIC InnoEnergy – A world class alliance of top European players with a proven track record • 13 companies, 10 research institutes, 13 universities • ~50% industry partners (incl. associated partners) • >50% of key research players in Europe • Covering the whole energy mix • Knowledge triangle balanced along all dimensions • Strong connection with VCs and local governments 4 16 Dec. 2009
Innoenergy offers • Education • Master programs • Generic and Thematic • Student mobility required • Entrepreneurship integrated in all programs • PhD programs • Program for Visiting Scholars • Resarch projects • Outreach projects • Opportunities for exchange on all levels KTH www.ecs.kth.se
KTH is a leading university in the energy field by… • Having a national but not at least an international perspective promoting • Student mobility • Teacher and researcher mobility • Joint initiatives in research • … KTH www.ecs.kth.se
Bjorn BirgissonMaterial KTH www.ecs.kth.se
History Industrial sectors for a Swedish Technical University
History • Long tradition of Material Science at KTH • KTH has over 50% of the Swedish research in fiber and polymer science • KTH is the largest centre in Sweden for Engineering Materials • KTH is a national hub for electronic and photonic materials • There are a very large number of centers of excellence in these fields
Structure of Material Research Physics, Chemistry Comp. Deve. Construction Materials core: Polymer, Steel, semiconductor materials, etc
Focus Areas OLD • Metallic engineering materials • Fiber and polymer materials (Soft materials) • Materials for photonic and electronic applications • Materials for energy applications • Advanced material characterisation
Situation in Lund MAX IV, the brightest synchrotron radiations source in the world! Operation: 2015 Budget 3.8 GSEK ESS, the most intense neutron source ever(?) Operation: 2018 Budget: 14 GSEK FOR SWEDEB THESE ARE VERY LARGE PROJECTS!!!
Materials – New (Inter)National Tools MAX-IV and ESS
Wallenberg Wood Science Center – New Materials from Trees www.wwsc.se WWSC is a joint research center at KTH and Chalmers
Goals • Multidisciplinary, broad competence platform in biomass materials and processing • Leading international position in Wood Science (and Engineering) for new materials RT Olsson et al, Nature Nanotechnology, 2010, published on-line
Focus: New materials from trees New components for the assembly of new materials Wood bioplastics Man-made fibers Functional wood fibers Cellulose absorbents Functional wood surfaces Biocomposites Inorganic/wood hybrids … Lignins, Hemicelluloses, Strong fibers Nanocellulose, Bark components, …
Supporting infrastructure At KTH • Electrum laboratory + Acreo environment • Albanova nano-fabrication facility National • Myfab – the Swedish micro- and nanofabrication network • Electrum Laboratory (KTH) • MC2 Nanofabrication laboratory (Chalmers University of Technology) • Ångström Microstructure Laboratory (Uppsala University)
Swedish Nano and Microfabrication Network Electrum Lab Ångström Lab Chalmers MC2 Lab Realize your nano visions • A distributed cleanroom facility • Access to all processes and equipment in the network • Backup for standard processes • Supporting academia and industry • Common marketing activities • Supported by • Swedish Research Council (Vetenskapsrådet) • The participating universities: • - KTH • - Uppsala University • - Chalmers
Leif KariAeronautical and Vehicle Engineering KTH www.ecs.kth.se
Here's what we are, what we do well, what our strengths and successes are • 365 researchers within all modes of transport • Collaborates with >80 companies Excellence in: • Transport system analysis • Vehicles on land, sea and air • Transportation infrastructure • ICT • Policy KTH Royal Institute of Technology • KTH Transport Platform
Where we want to go, what we want to be, what we could do better by leveraging a collaborative partnership • The mission of the KTH Transport Platform is to be an effective and efficient vehicle for delivering multidisciplinary research aiming for transport solutions servicing the society of tomorrow • We want to integrate policy, vehicle technology, infrastructure and systems research to transform the transport system into a greener, smarter, and safer system • We realizes that the problems we are facing today related to the transport sector require both research excellence and bold initiatives at the global level and international networks of world leading universities sharing the same vision. KTH Royal Institute of Technology • KTH Transport Platform
Joakim LundebergScience for Life Laboratory KTH www.ecs.kth.se
Background to Medical and Biomedical research at KTH School of Biotechnology 17 Professors; > 100 PhD Students 45 Research Leaders; > 220 Employees ‘Success stories’ Medical and Biomedical Platform • Enzyme catalysis – design, production and use • Microorganism physiology -> production and purification of proteins • Development of sequencing strategies and techniques -> genome and transcriptome sequencing • Fundamental glycoscience and development of analytical tools and biomaterials • Selection and design of proteins for biomedical purposes: diagnostics, therapeutics and protein purification. • Development of miniaturized devices for analytical purposes. • Annotation of the human proteome, diseased and healthy • Development of diagnostic tools • Development of computational tools for prediction of molecular interactions and biological processes SciLifeLab, center for massive biology (Pyrosequencing) Wood biotechnology (Tree genomics) Affibodies (Binding scaffold) Human Protein Atlas (Antibody proteomics) • Strong tradition in applied research • Top scientists - international networks • Long-term relations with relevant industries • Critical mass allows funding of “hot projects” • Right ingredients for interdisciplinary research • State-of-the-art instrumentation/infrastructure • Strong scientific environment - synergy effects
Interaction modes Master program • Master thesis (20 weeks) • Courses (complementary) Doctoral program • Research projects (exchange > 6 months) • Courses
Carl-Gustaf JanssonICT KTH www.ecs.kth.se
ICT at KTH Professor Carl Gustaf Jansson Coordinator, the ICT platform KTH Main Campus KTH Kista
ICT at KTH - Where we are today (figures from 2009) • A strong Research environment • Annual turnover 95 M Euro External funding 40 M Euro • Research Groups 30 Professors 90 • Research Centers 15 • An international Education environment • Post graduate students 430 Master students 1500 • Strong domination of foreign students which may change due to new fees • Few swedish students chose a term abroad • An already workinglocal Innovation system • KTH Innovation • KTH Business Liasion • Stockholm Innovation & Growth (STING) • Good collaboration with Research Institutes • SICS, ACREO and FOI • A strong Industrial environment • Kista Science City with large companies like Ericsson and • many SMEs, 500 ICT companies and 20.000 employees locally • but low mobility between Academia and industry
ICT at KTH - Where we want to go An even stronger Research environment Better sýnergies between KTH schools and centers through platform initiatives More tight interaction with institutes (learning from US and European practises) Strengthened national and Europeans research consortia (e.g SRAs and EIT KICs) Bilateral aggreements with international partner universities focussed on targeted research groups and research centers A balanced Education environment Improved examination rates and balanced funding models A stable influx of foreign students with a balance between different sources: EU, US and far east tuned to realistic fee levels More swedish students chosing to study a term abroad A more internationalized Innovation system and stronger interactions with industry Connecting Innovation Hubs in different European regions (EIT KICs) Learning from the innovation system and industrial collaboration schemes in US Internships, guest positions, mentor programs Improved fund raising capabilities
Nina WormbsPhilosophy and History of Technology KTH www.ecs.kth.se
Research School of Earth Society and Environment Scandinavian Studies History College of Media Student exchange Theory and Methodology of Science Research Ethics Environmental History Energy and Geopolitics Swedish Society, Culture and Industry in Historical Perspective Possibilities for collaboration Next round: Include Architecture and Urban Planning
Jacob KuttenkeulerEngineering Pedagogics KTH www.ecs.kth.se
On Engineering Education • Here's what we are: • A university with highly set goals to “produce” the best engineers who can really engineer! • CDIO – our framework for engineering education design • What we do well: • CDIO development & implementation since the start 2000, now with >50 collaborators • Experienced in integration of technical knowledge and engineering skills Our strengths and successes: Systematic program makeover at KTH using the CDIO approach Course level – program level alignment 10 years of systematic use of design-build projects Willing and able!
Educating Engineers who can Engineer • Here's where we want to go: • To the place where the students get what they came for – already from the start • To the place where programs and courses are aligned, in good sequence and build progression • What we could do better by leveraging a collaborative partnership: • Widen our perspective and learn from your iFoundry etc • Give students a wider perspective • Become better educators! • What we want to be: • The best educators in the class • Recognized as progressive educators