Ultimately our vision is about using science to make a difference in the world.

2. GRAND CHALLENGE GRAND CHALLENGE Ultimatelyour vision is aboutusing science to make a difference in the world. GRAND CHALLENGE GRAND CHALLENGE GRAND CHALLENGE GRAND CHALLENGE

3. Our Driving forces:ENTREPRENEURSHIP ･ INNOVATION ･ SUSTAINABLE FUTURE BASIC SCIENCES(The roots of scientificunderstanding)

4. Information & Communication Technology Materials Science Built Environment Life Science Nanoscience & Nanotechnology Production Energy Transport

5. [Chalmers’ terminology]; an area of interaction between research, innovation and education at Chalmers resulting in scientificexcellence and a potential to improvesustainability.

6. SCIENTIFIC EXCELLENCE • International alliances • Impact on society • Interaction across the knowledge triangle • Meetings across boundaries • Visibility and focus VISION FOR EXCELLENCE INFORMATION & COMMUNICATION TECHNOLOGY ENERGY PRODUCTION MATERIALS SCIENCE BUILT ENVIRONMENT LIFE SCIENCE NANOSCIENCE & NANOTECHNOLOGY TRANSPORT

7. INTERACTION ACROSS THE KNOWLEDGE TRIANGLE INNOVATION This form of interaction provides Chalmers with a vital and continuous supply of knowledge, competence and partners. RESEARCH EDUCATION

8. A UNIQUE MODEL STRATEGIC STEERING The Chalmers modelis a powerful instrument facilitatingbothoperational and strategicworkingprocesses. This freedom enableseach Area of Advance to perform to itsgreatest potential. DEPARTMENTS ･ A&S FIELDS OF EDUCATION AREA OF ADVANCE

9. MEETINGS ACROSS BOUNDARIES Each Area of Advance is an open meeting place where various parties can work together for a common solution – crossing the boundaries of academia, industry and society.

10. INTERNATIONAL INTEGRATION With excellence in research and education as ourcurrency, the Areas of Advancereinforce the university’scollaboration with partners all over the world. Attractingfurtheropportunitiesto excel.

11. Competence HOW THIS WORKS: Each area provides a hub of competence to achieve a common goal. Department Competence Competence Department Department Department

12. AN AREA OF ADVANCE OVERVIEW Active field Projects Excellence profile Excellence profile Excellence profile Active field Projects Active field Active field Active field Active field Projects Projects Projects Projects Projects

13. LEADERS Vice President, Areas of Advance Anne-Marie Hermansson Nanoscience &Nanotechnology Jari Kinaret Information &CommunicationTechnology Jan Grahn Transport Anna Dubois Materials Science Krister Holmberg Life Science Jens Nielsen Production Rickard Söderberg Energy Thore Berntsson Built Enviroment Nina Ryd

15. BUILT ENVIRONMENT OVERVIEW EXCELLENCE PROFILES EMERGING PROFILES • INFRASTRUCTURE • ENERGY IN BUILDINGS • STRATEGIC PLANNING AND PROCESSES • SMARTGEOMETRY • HEALTH IMPACT • Infrastructure for • sustainablemobility & transport • The building as a system • Regional and Urban planning • Parametric Design • Demography • Multi-scale • modeling ACTIVE FIELDS • Infrastructure for water and energy supply • Energy use and technology integration in buildings • Project management • Advance construction • Management and organization of large infrastructure projects • Indoor climate • Value driven design and briefing • Building physics BASIC SCIENCE

16. LINKS TO OTHERAREAS OF ADVANCE INFORMATION AND COMMUNICATION TECHNOLOGY LIFE SCIENCE Built Environment has links to several of the other Areas of Advance, in particular Energy, Production, and Transport. A prime example is the profile Energy in Built Buildings which is shared with the Area of Advance - Energy. Another example is the initiative of Future Urban Transport taken by the Area of Advance -Transport. TRANSPORT BUILT ENVIRONMENT MATERIALS SCIENCE PRODUCTION ENERGY NANOSCIENCE AND NANO- TECHNOLOGY

18. ENERGY OVERVIEW EXCELLENCE PROFILES HEAT AND POWER GENERATION MATERIALS FOR ENERGY CONVERSION/ APPLICATION TRANSPORT SYSTEMS AND INFRASTRUCTURE BUILDINGS – ENERGY USE AND EFFICIENCY ENERGY SYSTEMS INDUSTRY – ENERGY USE AND EFFICIENCY COMBUSTION AND GASIFICATION Smart Grids Biomass gasification Materials for energy production and transfer Combustion engines research The building as a system Energy efficiency and process integration Global sustainable systems and bridging technologies Wind Power Carbon capture technologies Materials for energy storage Electric and hybrid vehicles Construction and management processes Industrial biorefineries Technology impact assessment and innovating processes ACTIVE FIELDS Energy Storage Combustion and corrosion using biomass and waste fuels Materials for energy conversion Renewable fuels Energy use and technology integration in buildings Process technologies Local and regional energy systems planning Solar Heating and heat pump Technologies Sustainable transport solutions Nuclear Physics & Chemistry Fusion BASIC SCIENCE AppliedMechanicsAppliedMathematics

19. Energy efficiency and energy technologies in buildings LINKS TO OTHERAREAS OF ADVANCE Energy efficient wireless communication Smart Grids Research on high temperature corrosion for efficient energy production and industrial processes. Efficient batteries/energy storage and solar cells Catalysis and catalysts for sustainable energy systems BUILT ENVIRONMENT MATERIALS SCIENCE LIFE SCIENCE ENERGY INFORMATION AND COMMUNICATION TECHNOLOGY Biofuels and biochemicals TRANSPORT Co-operation in Swedish Hybrid Vehicle Centre - efficient engines, new power trains and technology for electric vehicles Alternative fuels with regard to production and use NANO SCIENCE AND NANO- TECHNOLOGY PRODUCTION Development of sustainable energy efficient products and production systems for manufacturing and process industry Basic photovoltaic research for efficient technology and materials

21. LIFE SCIENCE OVERVIEW EXCELLENCE PROFILES FOOD AND NUTRITION BIOENGINEERING SYNTHETIC BIOLOGY MATHEMATICAL BIOLOGY FERMENTATION TECHNOLOGY Metabolic Engineering Metabolic Models Biofuels and Biochemicals Bioactive Foods Medical Technology Macromolecular Interactions Bioinformatics Biopharmaceuticals Food Processing and Bioavailability Tissue Engineering ACTIVE FIELDS Synthetic Organelles Evolution Enzyme Technology Nutrition Pathway Modeling Food Availability Basic science Applied mathematics Applied chemistry BASIC SCIENCE

22. LINKS TO OTHERAREAS OF ADVANCE TRANSPORT INFORMATION AND COMMUNICATION TECHNOLOGY Medical Technology Tissue Engineering PRODUCTION MATERIAL LIFE SCIENCE ENERGY Biofuels and biochemicals BUILT ENVIRONMENT NANOSCIENCE AND NANO- TECHNOLOGY Macromolecular Interactions Synthetic Organelles

24. INFORMATION AND COMMUNICATION TECHNOLOGY OVERVIEW EXCELLENCE PROFILES SOFTWARE ENGINEERING & TECHNOLOGY ANTENNA SYSTEMS PHOTONICS MICROWAVE TECHNOLOGIES COMMUNICATION SYSTEMS PARALLEL & DISTRIBUTED SYSTEMS Transport & vehicles Telecommunications Energy & environment ACTIVE FIELDS Space & defence & security Infotainment,media Infotainment,media Software tools & production Life science Componentsuppliers Componentsuppliers BASIC SCIENCE

25. LINKS TO OTHERAREAS OF ADVANCE Bottom-up nanoelectronics Smart buildings with ICT PRODUCTION Packagingand production for electronics & photonics NANOSCIENCE AND NANO- TECHNOLOGY Sensors, communications, and signal processing for vehicles and transportation Safety critical automotive software BUILT ENVIRONMENT MATERIALS SCIENCE INFORMATION AND COMMUNICATION TECHNOLOGY New materialsfor electronics and photonics TRANSPORT ENERGY LIFE SCIENCE ENERGY Smart grid Green wireless Energy-efficient computing infrastructures Low-power electronic components and design eHealth Antennas for medical diagnostics and treatment

27. TRANSPORT OVERVIEW EXCELLENCE PROFILES SUSTAINABLE VEHICLES AND FUELS TRAFFIC SAFETY TRANSPORT EFFICIENCY & CUSTOMER ADAPTED LOGISTICS Efficient powertrains Vehicle operation and control Interplay and interfaces Traffic analysis Injury prevention ACTIVE FIELDS Vehicle concept development Demand for transport services Supply of transport services Accident prevention BASIC SCIENCE

28. LINKS TO OTHERAREAS OF ADVANCE Future Urban Transport ProductionLogistics/ Demand for transport services BUILT ENVIRONMENT PRODUCTION Intelligent transport systems INFORMATION AND COMMUNICATION TECHNOLOGY TRANSPORT LIFE SCIENCE MATERIALS SCIENCE ENERGY ENERGY NANOSCIENCE AND NANO- TECHNOLOGY Sustainable Vehicles and Fuels

30. MATERIALS SCIENCE OVERVIEW EXCELLENCE PROFILES • MATERIALS FOR • HEALTH • MATERIALS FOR • ENERGY • APPLICATIONS • SUSTAINABLE • MATERIALS • EXPERIMENTAL • METHODS • THEORY AND • MODELLING • Tissue and cell • engineering • Energy supply and • energy transfer • Materials from • renewable raw • materials • Advanced • characterization tools • and methods • Ab-initio modelling • Multi-scale • modeling ACTIVE FIELDS • Materials for • pharmaceuticals and • personal care • Energy storage • Recycling and • long term behavior • of materials • Instrumentation • projects at • large scale facilities • Nano-scale modelling • Multi-scale • modeling • Materials for • biosensing • Energy conversion • Reduction of • environmental impact • through materials research • Infrastructure for • new materials • synthesis • Macro/meso scale • modelling • Multi-scale • modeling • Materials for • food technology BASIC SCIENCE

31. LINKS TO OTHERAREAS OF ADVANCE INFORMATION AND COMMUNICATION TECHNOLOGY TRANSPORT PRODUCTION Materials for Energy Applications BUILT ENVIRONMENT MATERIALS NANOSCIENCEAND NANO- TECHNOLOGY ENERGY LIFE SCIENCE

33. NANOSCIENCE AND NANOTECHNOLOGY OVERVIEW EXCELLENCE PROFILES • NANOPHYSICS • NANOBIOPHYSICS • NANOCHEMISTRY • Quantum nanodevices • Nanocatalysis • Nanofluidics • Nanoelectronics Molecular nanoelectronics Molecular nanoelectronics ACTIVE FIELDS • Nanomaterials • Nanomaterials • Nanoelectromechanics • Nanosensors • Nanooptics • Nanoimaging BASIC SCIENCE

34. BUILT ENVIRONMENT PRODUCTION LINKS TO OTHERAREAS OF ADVANCE TRANSPORT MATERIAL NANOSCIENCE AND NANO- TECHNOLOGY • Nanomaterials Nanosensors INFORMATION AND COMMUNICATION TECHNOLOGY LIFE SCIENCE Nanoelectronics ENERGY Nanocatalysis

36. PRODUCTION OVERVIEW EXCELLENCE PROFILES SUSTAINABLE MANUFACTURING PROCESSES SUSTAINABLE PRODUCTION SYSTEMS SUSTAINABLE PRODUCT DEVELOPMENT Components manufacture Human and automation optimisation Sustainable product lifecycle platforms Process modelling and materials behaviour Production system performance Environment strategic product and production development and recycling ACTIVE FIELDS • Micro-fabrication Virtual production systems Virtual assembly and disassembly simulation and planning methods Virtual robust design and simulation BASIC SCIENCE

37. LINKS TO OTHERAREAS OF ADVANCE Our research is fundamentally based on science in mathematics, physics and/or chemistry and reaches across other Chalmers Areas of Advance: INFORMATION AND COMMUNICATION TECHNOLOGY LIFE SCIENCE TRANSPORT PRODUCTION MATERIALS SCIENCE BUILT ENVIRONMENT ENERGY NANOSCIENCE AND NANO-TECHNOLOGY