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NANO futures Workshop

NANO futures association. NANO futures Workshop. NANOfutures Boosting European Competitiveness in Nanotechnology Industrial Technologies 2012 Aarhus, 20 June 2012. NANO futures European Technology Innovation Platform. Background. Vision and Objectives. Roadmapping Approach.

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NANO futures Workshop

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  1. NANOfutures association NANOfutures Workshop NANOfutures Boosting European Competitiveness in Nanotechnology Industrial Technologies 2012 Aarhus, 20 June 2012

  2. NANOfutures European Technology Innovation Platform Background Vision and Objectives Roadmapping Approach Roadmap Overview Applications & Products by Sectors Expected Impact Conclusion Industrial Technologies 2012 Aarhus, 20 June 2012

  3. Background Interest in Nanotechnology has increased enormously in the last years due to the technology revolution potential it holds (> 3 billion of Euros of worldwide spending) • Economic and social benefits from these large investments in research are nevertheless not fully appearing, due to: • gap between research efforts and industrial and user needs • dispersion and fragmentation of efforts • need to addressbroader socioeconomic challenges going beyond sectorial technological gaps In order to contribute to the competitiveness and sustainability of EU, meeting the Grand Challenges of our time, a cross-sectorial approach is needed, involving all relevant stakeholders. Industrial Technologies 2012 Aarhus, 20 June 2012

  4. NANOfuturesat a glance NANOfutures is a new generation cluster of ETPs operating on NANOTECHNOLOGY. European Policies & Objectives Regional & National Programs European Commission Programs • It addresses cross-sectorial needs, joining the efforts of all the stakeholders; • It aims at reducing fragmentation, aligning research and innovation efforts for the competitiveness of European nanotechnology • it aims at meetinggrandsocietaland economical challenges through fostering the development of sustainable nano-enabled products Industrial Technologies 2012 Aarhus, 20 June 2012 4

  5. From industrial association and networks From research institute and universities Plus close cooperation with 11 European Technology Platforms From industrial sectors, NANOfuturesStructure NANOfuturescomposed of around fast growing 700 members Industrial Technologies 2012 Aarhus, 20 June 2012

  6. NANOfutures Steering Committee RESEARCH and TECHNOLOGY NANOfuturesStructure INDUSTRIALIZATION • Chair: Paolo Matteazzi (MBN NanomaterialiaSpA, IT) • Co-chairs: Prof. Kiparissides (CERTH, GR) and Peter Krüger (Bayer Material Science, DE) COMMUNICATION SAFETY RESEARCH • 10 Horizontal working groups chairs INDUSTRIAL SAFETY • 11 ETP representatives, appointed by the ETPs STANDARDIZATION REGULATION Tech.Transfer and Innovation Financing NETWORKING SKILLS AND EDUCATION Industrial Technologies 2012 Aarhus, 20 June 2012

  7. NANOfutures European Technology Innovation Platform Background Vision and Objectives Roadmapping Approach Roadmap Overview Applications & Products by Sectors Expected Impact Conclusion Industrial Technologies 2012 Aarhus, 20 June 2012

  8. NANOfutures Vision By 2015, Nanotechnology World Market Size would hit 1.1 trillion USD in a broad range of sectors (chemical manufacturing, pharmaceuticals, aerospace, electronics, materials etc.). By 2025, nanotechnology is expected to be a mature yet still growing industry, with countless mainstream products in all different industrial sectors. In this context, Europe aims to play a market leader position, increasing its competitiveness in all different sectors where nanotechnology may have a strong added value. The growth and commercialization of nanotechnology must be guided and fostered by taking care of social and sustainability aspects. Industrial Technologies 2012 Aarhus, 20 June 2012

  9. NANOfutures Vision • If effective alignment of private and public efforts over promising areas is guaranteed from short to long term, European Nanotechnology is expected to give an outstanding contribution to major Societal challenges of our time: • Health, demographic change and wellbeing; • Food security, sustainable agriculture, marine and maritime research and the bio-economy; • Secure, clean and efficient energy; • Smart, green and integrated transport; • Climate action, resource efficiency and raw materials; • Inclusive, innovative and secure societies. Industrial Technologies 2012 Aarhus, 20 June 2012

  10. Roadmapping Objectives • NANOfuturesintegrated Industrial and Research Roadmapaims to: • address European key nodes in terms of cross-sectorial research, technology and innovation issues • cover broad socio-economic challenges to the implementation and commercialisation of sustainable and safe nanotechnology enabled solutions • Have a market-driven value chain approach with a set of tech and non-tech actions along the identified value chains • have a long term horizon (>2025) while including detailed implementation plan up to 2020. Industrial Technologies 2012 Aarhus, 20 June 2012

  11. NANOfutures European Technology Innovation Platform Background Vision and Objectives Roadmapping Approach Roadmap Overview Applications & Products by Sectors Expected Impact Conclusion Industrial Technologies 2012 Aarhus, 20 June 2012

  12. NANOfuturesis structured as a hub for nanotechnologies and the roadmapping activity reflects this structure The starting point of roadmapping was based on contributions from 11 ETPs and from the NANOfutures members (industries, universities, institutes) divided in 10 Horizontal Working Groups Working Group ETP Industrial Technologies 2012 Aarhus, 20 June 2012

  13. The ETPs provided the needs (50) for their economical growth The Working groups analyzed the ETP needs, based on common horizontal issues from industry to safety, from research to communication Working Group ETP Industrial Technologies 2012 Aarhus, 20 June 2012

  14. Key Nodes From the clustering of the ETP needs with the horizontal issues emerged 5 Key Nodes. For each of them a leading expert and a group of experts were appointed in order to translate backward the KNs in Actions and Markets Working Group ETP Industrial Technologies 2012 Aarhus, 20 June 2012

  15. Key Nodes Value Chains 7 Value Chains were identified by the experts. The VCs constitute the backbone of the roadmap Working Group ETP Industrial Technologies 2012 Aarhus, 20 June 2012

  16. Key Nodes Value Chains Markets Several Markets were outlined: the WGs will analyze them in order to provide specific guidelines for the development of nanotechnologies Working Group ETP Industrial Technologies 2012 Aarhus, 20 June 2012

  17. NANOfutures Roadmapping The loop is almost completed and will be the basis for future activities of NANOfutures ETIP KeyNodes Leaders group Working Groups 7 value chains and several markets, that may use nanotech to successfully address the economy and society challenges 10 Horizontal Working Groups identified 5 KeyNodesbased on ETP’s needs Working Groups Each market will be analyzed and bottlenecks and missing steps outlined, tracing the roadmap to Horizon 2020 ETPs 11 European Technology Platforms described their needs Industrial Technologies 2012 Aarhus, 20 June 2012

  18. The Meaning of Value Chains The NANOfutures collaborative environment has a great potential because it is an hub for all the necessary actors to complete the bridge. Pilot Lines Technological Facilities Globally Competitive Manufacturing Facilities PULL Technology Products Production Science MARKET KNOWLEDGE Industrial Consortia Competitive Manufacturing Technological Research PUSH VALUE CHAIN Industrial Technologies 2012 Aarhus, 20 June 2012

  19. The Meaning of Value Chains Within a Value Chain the Production Chain was highlighted, in order to evidence the missing steps in order to have the product. METROLOGY COMPONENTS TOOLS ASSEMBLY MATERIALS MODELLING FINAL PRODUCT DESIGN PRODUCT PRODUCTION CHAIN VALUE CHAIN Industrial Technologies 2012 Aarhus, 20 June 2012

  20. Sustainability overarch the chains addressing the societal challenges. The Meaning of Value Chains EDUCATION & TRAINING STANDARDIZATION SAFETY ENVIRONMENT COMMUNICATION REGULATION SUSTAINABILITY GROWTH SOCIETAL CHAIN PRODUCTION CHAIN VALUE CHAIN Industrial Technologies 2012 Aarhus, 20 June 2012

  21. The Meaning of Value Chains Value chain actions are aligned with Horizon 2020 structure (Excellent Science, Societal Challenges, Industrial Leadership). Societal Challenges Excellent Science Industrial Leadership KNOWLEDGE DESIGN GROWTH MARKET PRODUCTS SUSTAINABILITY VALUE CHAINS Industrial Technologies 2012 Aarhus, 20 June 2012

  22. Chains and Roadmap SOCIETAL CHAIN Cross-cutting actions that overarch the roadmap PRODUCT CHAIN 20 Possible Markets Identified 5 Key Nodes and 7 Value Chain identified VALUE CHAIN MARKETs PRODUCTs SUSTAINABILITY The value chains constitute the backbone on which is made the roadmap The product chains bring the roadmap near to the applicative and measurable field KNOWLEDGE DESIGN GROWTH The societal chains assure the sustainability of the roadmap Industrial Technologies 2012 Aarhus, 20 June 2012

  23. NANOfutures European Technology Innovation Platform Background Vision and Objectives Roadmapping Approach Roadmap Overview Applications & Products by Sectors Expected Impact Conclusion Industrial Technologies 2012 Aarhus, 20 June 2012

  24. Roadmap Overview Nano-Micro scale manufacturing ValueChains Transportation Nano structures and composites Integration of nano Packaging Functional Fluids Textile and sport sector Energy and ICT (structuring, surface or nanoporous materials) Nano-enabled surfaces Safety & Sustainability Lightweight multifunctional materials and sustainable composites Infrastructure for Multiscale Modelling and Testing Cross Sectorial Non-Technological Actions Direct manufacturing Construction and building Alloys Ceramics, Intermetallics Design, Modelling and Testing of materials Transportation Semi finished 3d structures for optoelectronic Structured Surfaces Medicine Nano-enabled surfaces for multi-sectorial applications Construction and buildings ICT (Nanoelectronics, photonics) Transportations Key Nodes Medicine (Bio-sensors, regen. medicine) Industrial Technologies 2012 Aarhus, 20 June 2012

  25. Roadmap Focus: VCs & Markets VC2 - Nano-enabled surfaces for multi-sectorial applications Plasma and Vacuum Engineered Surfaces VC1 - Lightweight multifunctional materials and sustainable composites Transportation Packaging Energy Wet Engineered Surfaces Construction and buildings Textile and sport sector ICT VC4 Alloys Ceramics, Intermetallics Construction and building VC5 Functional Fluids Direct manufacturing VC6 Integration of nano Transportation Finished net shaped Consumer Products (Cosmetics & Household Cleaning) Energy Harvesting & Conversion Catalysis and filtration Semi finished 3D structures for nanoelectronics & photonics Medicine &Pharma ICT Functional Packaging VC3 Structured Surfaces Construction and buildings VC7 Infrastructure for Multiscale Modelling and Testing ICT (Nanoelectronics, photonics, sensors) Transportation ICT (Thermal & Electrical Management) Medicine (Bio-sensors, Lab on a Chip, regen. medicine) Textile and passive funct. Energy (PV batteries, harvesting) Complex Adaptive Systems for complete product design Cross Sectorial Non-Technological Actions Industrial Technologies 2012 Aarhus, 20 June 2012

  26. Roadmap Focus: VCs & Markets ETPs Each Market meetsmany ETP Markets Market 2 Value Chains Market 3 Market 4 Market 1 Market 5 Each Market Meets manySocietal Challenges Each ETP meetsmany Societal Challenges EU societal challenges Industrial Technologies 2012 Aarhus, 20 June 2012

  27. ETPs Market & Value Chain Industrial Technologies 2012 Aarhus, 20 June 2012

  28. Roadmap Focus: VCs & Markets VC1 - Lightweight multifunctional materials and sustainable composites Textile and sport sector Energy Packaging Transportation Construction and buildings ICT VC2 - Nano-enabled surfaces for multi-sectorial applications VC4 Alloys Ceramics, Intermetallics Wet Engineered Surfaces Plasma and Vacuum Engineered Surfaces Energy Harvesting & Conversion ICT Functional Packaging VC3 Structured Surfaces Textile and passive funct. Energy (PV batteries, harvesting) Medicine (Bio-sensors, Lab on a Chip regenerative medicine) Construction and buildings ICT (Nanoelectronics, photonics, sensors) Transportation Industrial Technologies 2012 Aarhus, 20 June 2012

  29. VC5 Functional Fluids Construction and building Medicine &Pharma Transportation Consumer Products (Cosmetics & Household Cleaning) ICT (Thermal & Electrical Management) VC6 Integration of nano Catalysis and filtration Semi finished 3D structures for nanoelectronics and photonics Direct manufacturing Finished net shaped VC7 Infrastructure for Multiscale Modelling and Testing Complex Adaptive Systems for complete product design Industrial Technologies 2012 Aarhus, 20 June 2012

  30. ETPs Direct answers to the needs Market & Value Chain Industrial Technologies 2012 Aarhus, 20 June 2012

  31. ETP focus on specific VCs VC4 Alloys Ceramics, Intermetallics VC6 Integration of nano VC2 - Nano-enabled surfaces for multi-sectorial applications VC3 Structured Surfaces 3D structures for nanoelectronics and photonics ICT Functional Packaging Medicine (Bio-sensors, Lab on a Chip, Regenerative medicine) Plasma and Vacuum Engineered Surfaces VC5 Functional Fluids ICT (Nanoelectronics, photonics, sensors) ICT (Thermal & Electrical Management) Wet Engineered Surfaces VC4 Alloys Ceramics, Intermetallics VC7 Infrastructure for Multiscale Modelling and Testing VC6 Integration of nano VC1 - Lightweight multifunctional materials and sustainable composites 3D structures for nanoelectronics and photonics Energy Harvesting & Conversion Complex Adaptive Systems for complete product design Semi finished VC6 Integration of nano VC3 Structured Surfaces VC7 MultiscaleModelling Cross Sectorial Non-Technological Actions Complex Adaptive Systems for design 3D structures for nanoelectronics and photonics Medicine(Bio-sensors, Lab on a Chip, Regenerative medicine) Finished net shaped Semi finished Industrial Technologies 2012 Aarhus, 20 June 2012

  32. ETP focus on specific VCs VC4 Alloys Ceramics, Intermetallics VC1 - Lightweight multifunctional materials and sustainable composites VC6 Integration of nano Energy Harversting & Conversion VC3 Structured Surfaces VC5 Functional Fluids Semi finished Catalysis and filtration Construction and buildings Construction and buildings Construction and building VC6 Integration of nano Semi finished Catalysis and filtration 3D structures for nanoelectronics and photonics Finished net shaped VC3 Structured Surfaces Cross Sectorial Non-Technological Actions VC5 Functional Fluids Medicine &Pharma Medicine (Bio-sensors, Lab on a Chip, Regenerative Medicine) VC7 Infrastructure for MultiscaleModelling VC1 - Lightweight multifunctional materials and sustainable composites VC3 Structured Surfaces Complex Adaptive Systems for complete product design Textile and passive functionalities Textile and sport sector Industrial Technologies 2012 Aarhus, 20 June 2012

  33. ETP focus on specific VCs VC7 Infrastructure for MultiscaleModelling VC6 Integration of nano VC3 Structured Surfaces ICT (Nanoelectronics, photonics, sensors) 3D structures for nanoelectronics and photonics Complex Adaptive Systems for complete product design VC7 Infrastructure for MultiscaleModelling Cross Sectorial Non-Technological Actions Complex Adaptive Systems for complete product design VC3 Structured Surfaces VC5 Functional Fluids VC1 - Lightweight multifunctional materials and sustainable composites Transportation Transportation Transportation VC6 Integration of nano Cross Sectorial Non-Technological Actions VC7 MultiscaleModelling VC5 Functional Fluids Catalysis and filtration • Complex Adaptive Systems for complete product design Consumer Products (Cosmetics & Household Cleaning) Medicine&Pharma VC2 - Nano-enabled surfaces for multi-sectorial applications Plasma and Vacuum Engineered Surfaces Industrial Technologies 2012 Aarhus, 20 June 2012 Wet Engineered Surfaces

  34. ETPs Direct answers to the needs EU societal challenges Industrial Technologies 2012 Aarhus, 20 June 2012

  35. Societal Challenges focuson specific VCs Some examples: VC4 Alloys Ceramics, Intermetallics VC6 Integration of nano VC1 - Lightweight multifunctional materials and sustainable composite … Energy Harvesting & Conversion Energy Catalysis and filtration Transportation Climate action, resource efficiency and raw materials; VC3 Structured Surfaces VC1 - Lightweight multifunctional materials and sustainable composites VC7 Infrastructure for Multiscale Modelling and Testing VC4 Alloys Ceramics, Intermetallics • Smart, green and integrated transport • Secure, clean and efficient energy Complex Adaptive Systems for complete product design Construction and buildings Energy Harvesting & Conversion Transportation VC1 - Lightweight multifunctional materials and sustainable composites VC5 Functional Fluids … Transportation Transportation Industrial Technologies 2012 Aarhus, 20 June 2012

  36. Societal Challenges focuson specific VCs Some examples: VC4 Alloys Ceramics, Intermetallics VC3 Structured Surfaces Cross Sectorial Non-Technological Actions … ICT (Nanoelectronics, photonics, sensors) ICT Functional Packaging • Inclusive, innovative and secure societies VC3 Structured Surfaces VC1 - Lightweight multifunctional materials and sustainable composites … Medicine (Bio-sensors, Lab on a Chip, regen. medicine) Packaging • Food security, sustainable agriculture, marine research and the bio-economy VC3 Structured Surfaces VC1 - Lightweight multifunctional materials and sustainable composites VC5 Functional Fluids • Health, demographic change and wellbeing; … Consumer Products (Cosmetics & Household Cleaning) Medicine (Bio-sensors, Lab on a Chip, regen. medicine) Textile and sport sector Industrial Technologies 2012 Aarhus, 20 June 2012

  37. Roadmap Focus: VCs & Markets Each Market is related with more than one ETP Each ETP is related with more than one Market Reliability of the system is guaranteed by integration and complementarities of the actions Industrial Technologies 2012 Aarhus, 20 June 2012

  38. Roadmap Overview MARKET DEFINITION FINAL PRODUCT TOOLS MATERIALS MODELLING METROLOGY COMPONENTS ASSEMBLY WASTE TREATMENT TRL 7-8 TRL 5-6 TRL 1-4 For each market the Value chain is highlighted The action are evaluated for their Technology Readiness Level from 1 to 8 (from tech assessment to production implementation) Industrial Technologies 2012 Aarhus, 20 June 2012

  39. Roadmap Overview MARKET DEFINITION FINAL PRODUCT TOOLS MATERIALS MODELLING METROLOGY COMPONENTS ASSEMBLY WASTE TREATMENT ACTION TRL 7-8 ACTION ACTION TRL 5-6 TRL 1-4 The Value Chain includes actions at Short Term, 2013-2016 at Medium Term: 2017-2020 at Long Term: 2020-2025 and beyond Industrial Technologies 2012 Aarhus, 20 June 2012

  40. Roadmap Overview MARKET DEFINITION FINAL PRODUCT TOOLS MATERIALS MODELLING METROLOGY COMPONENTS ASSEMBLY WASTE TREATMENT ACTION TRL 7-8 ACTION ACTION TRL 5-6 TRL 1-4 NON-TECH ACTIONS NON-TECH ACTIONS NON-TECH ACTIONS Non technological actions complete the definition of the market Industrial Technologies 2012 Aarhus, 20 June 2012

  41. Roadmap Overview The identified actions will address two main outcomes in the roadmap: The identification of markets and value chains that require only few actions to be completed. The identification of common actions (technological or not) from different markets and value chains. Industrial Technologies 2012 Aarhus, 20 June 2012

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