1. Development of micro and nano technologies roadmap for 2020
Lambertini Vito

2. European Technology Innovation Platform
NANOfutures
European Technology Innovation Platform
Roadmapping Approach
Roadmap Overview
Roadmap for Applications & Products
Roadmap for grand challenges
Conclusion

3. European Technology Innovation Platform
NANOfutures
European Technology Innovation Platform
Roadmapping Approach
Roadmap Overview
Roadmap for Applications & Products
Roadmap for grand challenges
Conclusion

4. Roadmapping Approach NANOfutures - Grand Challenges
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. 4

5. 10 Horizontal working groups
Roadmapping Approach
RESEARCH and TECHNOLOGY
NANOfutures – Industrial sectors
INDUSTRIALIZATION
11 ETPs
COMMUNICATION
SAFETY RESEARCH
INDUSTRIAL SAFETY
STANDARDIZATION
REGULATION
Tech.Transfer and Innovation Financing
NETWORKING
SKILLS AND EDUCATION 5

6. European Technology Innovation Platform
NANOfutures
European Technology Innovation Platform
Roadmapping Approach
Roadmap Overview
Roadmap for Applications & Products
Roadmap for grand challenges
Conclusion

7. Roadmap Overview Value Chains Key Nodes Nano-Micro scale manufacturing
Integration of nano
Nano-Micro scale manufacturing
Functional Fluids
Lightweight multifunctional materials and sustainable composites
Nano structures and composites
Infrastructure for Multiscale Modelling and Testing
Cross Sectorial Non-Technological Actions
Alloys Ceramics, Intermetallics
Structured Surfaces
Nano-enabled surfaces
Nano-enabled surfaces for multi-sectorial applications
Design, Modelling and Testing
of materials
Key Nodes
Safety &
Sustainability

8. NON-TECH ACTIONS to complete the definition of the market
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
LEGENDA:
NON-TECH ACTIONS to complete the definition of the market
SHORT TERM
NON-TECH ACTIONS
MEDIUM TERM
LONG TERM

9. NON- TECHNOLOGICAL CROSS- CUTTING ACTIONS FOR ALL VALUE CHAINS
TARGETS
Smart Sustainable Growth
effective technology transfer and innovation financing actions, boosting private investment and industrial uptake
must address the Grand Challenges of our time
Ensure high levels of safety
Research into effects on human health and environment, life-cycle assessment, test methods /equipment
Further review & effective implementation of standardization and regulation
Consolidate Public Trust
Dialogue and Education
Effective Communication
STANDARDIZATION
ENVIRONMENT
COMMUNICATION & NETWORKING
TECH TRANSFER & INNOVATION FINANCING
SAFETY
REGULATION
EDUCATION

10. NON- TECHNOLOGICAL CROSS- CUTTING ACTIONS: DETAILS/1
FINAL PRODUCT
TOOLS
MATERIALS
MODELLING
METROLOGY
COMPONENTS
ASSEMBLY
WASTE TREATMENT
Control potential release during professional and/or consumer use.
Assess and control potential release to workplace air during component manufacturing and assembly
Understand the hazardous nature of the material
Assess and control potential releases to workplace air during manufacturing and life cycle
Control potential worker exposure during recycling & disposal
Adopt safety by design into material selection
SAFETY
Recommend safety advice to professional and/or consumer users
Apply technologies/techniques that maximise the extent to which the material is incorporated into the product in order to i) maximise functionality and ii) minimise releases to the environment
Characterise and control potential release to the environment (mainly water) from the developed processes
Understand fate and behaviour of these materials in the environment
Characterise and control potential release to the environment (air/soil/water) from the developed processes
Apply standards/SOPs for safe disposal of these materials
ENVIRONMENT
Apply standards/SOPs for safe handling of these materials , considering the whole life cycle
STANDARDIZATION
Appropriate level of regulation to address EHS issues whilst supporting innovation
Apply standards/SOPs for safe handling of these materials
Appropriate level of regulation to address EHS issues whilst supporting innovation
REGULATION
Appropriate nomenclature for nano

11. NON- TECHNOLOGICAL CROSS- CUTTING ACTIONS: DETAILS/2
FINAL PRODUCT
TOOLS
MATERIALS
MODELLING
METROLOGY
COMPONENTS
ASSEMBLY
WASTE TREATMENT
Communication of knowledge regarding hazardous nature of the material down the supply chain.
More information flow and dialogue between industry and educational experts
Initiate dialogue with the public (with industry, regulators etc. ) about future potential benefits about nanotechnology.
Develop tools to assess societal impacts of nanoproducts . Communication and clustering actions across different sectors and between Academia and Industry, Infrastructure facilities and Society.
Better Regional/National Funding Agencies Coordination
Effective communication to the EU society on the social and economic impact.
To foster more dialogue among policy makers about best practices in nano
COMMUNICATION & NETWORKING
Extra EU trans-national cooperation
& Networking
Actions for the benefit of SMEs
Involvement of investors and Investment readiness programmes for SMEs
Cross-sectorial TT programme
TT from academia to industry.
New business strategies and business models for nano-enabled products
TECH TRANSFER & INNOVATION FINANCING
ICT and TT commercialization tools
Support infrastructure for TT service (eco-system of labs and skilled persons)

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

13. VC1c - LIGHTWEIGHT MULTIFUNCTIONAL MATERIALS and SUSTAINABLE COMPOSITES for TRANSPORTATION
FINAL PRODUCT
TOOLS
MATERIALS
MODELLING
METROLOGY
COMPONENTS
ASSEMBLY
WASTE TREATMENT
Integration of novel materials into existing production and assembly lines
Low cost and large scale functionalized composites
LCA and ELV
TRL 7-8
Development of cost effective industrial scale technologies for synthesis and technologies for dispersion/exfoliation (extrusion)
Thin glass/
Plastic glazing
Multilayer materials
Thin glass
Metal foams based panels
Ceramic parts
Metal-foam sandwich panel structures
Ceramic parts
Composites with added functionality
Multilayer materials
Thin glass
Design of multifunctional materials tailored for different needs
Monitoring of materials structure, properties and functionalities
Advanced smart multifunctional foams
TRL 5-6
LEGENDA:
Adaptation/modification of novel technologies for production on industrial scale smart polymer; implementation of these materials into different devices
Development of methods for functionalization during synthesis to reduce production steps and alignment of nano-objects
SHORT TERM
Understanding of relationships morphology/functionality/triggers of multifunctional polymers
Characterization and monitoring of materials structure, properties and functionalities
MEDIUM TERM
TRL 1-4
LONG TERM
SAFETY
Assess and control potential human exposure during assembly and finishing of products
SAFETY
Characterise and control potential release of nanoparticles during waste treatment and reprocessing. Understand potential environmental hazards resulting from recycling processes
NON-TECH ACTIONS specific to the value chain

14. VC1f - LIGHTWEIGHT MULTIFUNCTIONAL MATERIALS and SUSTAINABLE COMPOSITES for CONSTRUCTION & BUILDING
FINAL PRODUCT
TOOLS
MATERIALS
MODELLING
METROLOGY
COMPONENTS
ASSEMBLY
WASTE TREATMENT
Integration of novel materials into existing production and assembly lines
Low cost and large scale functionalized composites
LCA of the process and integration of wastes in the LCA analysis
TRL 7-8
Composites: development of materials and construction parts
Advanced smart multifunctional foams and multilayer components
Multilayer components
Adaptation of machines and process’ parameters to maintain functionalities
Monitoring of materials structure, properties and functionalities
Multilayer barrier materials
Composites with added functionality
TRL 5-6
Designing of multifunctional materials tailored for different needs
Adaptation/modification of novel technologies for production on industrial scale smart polymer and concrete
Development of methods for functionalization during synthesis to reduce production steps and alignment of nano-objects
LEGENDA:
Characterization and monitoring of mateials structure, properties and functionalities
SHORT TERM
Materials modelling, thermal simulation and process design
MEDIUM TERM
TRL 1-4
LONG TERM
SAFETY
Characterise and control potential release of nanoparticles during waste treatment and reprocessing.
Understand potential environmental hazards resulting from recycling processes
SAFETY
Assess and control potential human exposure during assembly and finishing of products
NON-TECH ACTIONS specific to the value chain

15. ROADMAPS for ALL VALUE CHAINS and RELATED MARKETS

16. European Technology Innovation Platform
NANOfutures
European Technology Innovation Platform
Roadmapping Approach
Roadmap Overview
Roadmap for Applications & Products
Roadmap for grand challenges
Conclusion

17. PRODUCTS AND APPLICATIONS FOR TRANSPORTATION
Long time, low cost fuel cell membranes and batteries; Low friction engines & lubricants; Smart glass surfaces; Lightweight metal or plastic sheet for chassis; efficient tires, wiper blades, seals; sustainable lightings and heating systems; smart sensors and radar systems
Involved Value Chains
Enabling technologies:
nanocomposites, nano-enabled thin glasses, metal-foams sandwitch panels, ceramic structures, nanoporous structures, coatings, structured surfaces and functional fluids tuned for transportation
VC1,VC2,VC3,VC4,VC5,VC6,VC7
Related actions
Addressing Grand Challenges:
Smart, green and integrated transport;
Climate action, resource efficiency and raw materials.
ETPs

18. PRODUCTS AND APPLICATIONS FOR ENERGY
Efficient catalysis & carbon capture and storage -CCS (pollution control in fuels, in geothermal etc.)
solid state lighting
(LED, OLED, PLED)
Advanced Solar cells (Including organic & hybrid PV)
Storage technologies (hybrid batteries, gas, hydrogen). Power electronics for industrial applications and engine management)
Target Market Size :
- In 2030, at least 30% shares of renewables in gross final energy consumption*
-In 2035 renewables, including hydro, produce roughly terawatthours
(TWh) in the world**
Involved Value Chains: VC1, VC2, VC3, VC4, VC6 and VC7
Multifunctional and smart polymer nanocomposites, multilayer structures, porous structures, metal alloy, ceramics, intermetallics, nanostructured surfaces, coatings and paints for energy generation, harversting, storage and distribution/management needs (high barrier properties for energy cell, enhanced gas absorption and trapping, efficient energy transmission, magnetic storage, catalytic structures and coatings, power electronics) .
Addressing Grand Challenges:
Secure, clean and efficient energy;
Smart, green and integrated transport;
Climate action, resource efficiency and raw materials;
ETPs
*Source:
**Source:

19. CONSTRUCTION & BUILDINGS TEXTILE AND SPORT SECTORS
Applications & Products
ENERGY
TRANSPORTATION
CONSTRUCTION & BUILDINGS
MEDICINE & PHARMA
ICT
TEXTILE AND SPORT SECTORS
PACKAGING
CONSUMER GOODS

20. European Technology Innovation Platform
NANOfutures
European Technology Innovation Platform
Roadmapping Approach
Roadmap Overview
Roadmap for Applications & Products
Roadmap for grand challenges
Conclusion

21. FROM SOCIETAL CHALLNGES to PRODUCTS
Societal Challenges
Applications & Products
Cross KET Value chains
Technologiocal and non-techn actions
Health, demographic change and wellbeing;
Food security, sustainable agriculture, marine and maritime research;
Clean and efficient energy;
Green transport;
Climate action, resource efficiency and raw materials;
Inclusive, innovative and secure societies.
Textile and sport sector
VC1 Lightweight multifunctional mat. and sustainable composites
ICT
Medicine &Pharma
VC2 Nano-enabled surfaces for multi-sectorial applications
Construction and buildings
Transportation
VC3 Structured Surfaces
Energy
Packaging
VC4 - Alloys Ceramics, Intermetallics
Direct manufacturing
VC5 Functional Fluids
Consumer Products (Cosmetics & Household Cleaning)
VC6 Integration of nano
VC7 Infrastructure for Multiscale Modelling and Testing

22. FROM SOCIETAL CHALLNGES to PRODUCTS
Societal Challenges
Applications & Products
Cross KET Value chains
Technologiocal and non-techn actions
Cost effective industrial scale synthesis and dispersion of nano-objects
Smart, green and integrated transport;
Climate action, resource efficiency and raw materials.
Transport
Building & Construction
Energy
Packaging
VC1 Lightweight materials and sustainable composites for TRANSPORTATION
VC2, VC3, VC4, VC5, VC6, VC7 for TRANSPORTATION
VC1, VC2, VC3, VC5, VC6, VC7 for CONSTRUCTION
VC1, VC2, VC3, VC4, VC6, VC7 for ENERGY …
Metal-foam sandwich panel structures
Integration of novel materials into existing production and assembly lines
Multilayer materials
Thin glass
Monitoring of materials structure, properties and functionalities
Functionalization methods during synthesis to reduce production steps
Design of multifunctional materials tailored for different needs
Characterization and monitoring of materials structure, properties and functionalities
Smart polymer on industrial scale; implementation of these materials into different devices
Green and large scale functionalized composites
Understanding of relationships morphology/functionality/triggers of multifunctional polymers
Human exposure
Characterise and control potential release of nanoparticles during waste treatment and reprocessing.
SAFETY
Common NON-TECH ACTIONS to all value chain

23. European Technology Innovation Platform
NANOfutures
European Technology Innovation Platform
Roadmapping Approach
Roadmap Overview
Roadmap for Applications & Products
Roadmap for grand challenges
Conclusion

24. Conclusion
The NANOfutures Integrated Research and Innovation Roadmap has been drafted, focusing on market-driven value chains and including also broad cross-cutting actions.
The Roadmap has been circulated for further development (definition of expected budget, finalization of non-tech actions specific to the value chains) among ETPs, Working Groups and Key Node experts.
The Final Roadmap will be released at the end of July, but it will be a living document!!