NANOfutures
association
NANOfutures Workshop
NANOfutures Boosting European Competitiveness in
Nanotechnology
Industrial Technologies 2012
Aarhus, 20 June 2012
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
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 address broader 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
NANOfutures at a glance
NANOfutures is a new generation
cluster of ETPs operating on
NANOTECHNOLOGY.

European
Policies &
Objectives
Regional
& National
Programs
It addresses cross-sectorial
needs, joining the efforts of all
the stakeholders;
European
Commission
Programs

It
aims
at
reducing
fragmentation,
aligning
research
and
innovation
efforts
for
the
competitiveness of European
nanotechnology

it aims at meeting grand
societal
and
economical
challenges through fostering
the development of sustainable
nano-enabled products
Industrial Technologies 2012 Aarhus, 20 June 2012
NANOfutures Structure
NANOfutures composed of
around fast growing 700
members
From industrial sectors,
From industrial
association and
networks
From research
institute and
universities
Plus close cooperation with
11 European Technology Platforms
Industrial Technologies 2012 Aarhus, 20 June 2012
NANOfutures Structure
NANOfutures Steering Committee
• Chair: Paolo Matteazzi (MBN Nanomaterialia SpA, IT)
• Co-chairs: Prof. Kiparissides (CERTH, GR) and
Peter Krüger (Bayer Material Science, DE)
RESEARCH and
TECHNOLOGY
INDUSTRIALIZATION
COMMUNICATION
SAFETY RESEARCH
• 10 Horizontal working groups chairs
• 11 ETP representatives, appointed by the ETPs
INDUSTRIAL SAFETY
STANDARDIZATION
REGULATION
Tech.Transfer and
Innovation Financing
NETWORKING
SKILLS AND
EDUCATION
Industrial Technologies 2012 Aarhus, 20 June 2012
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
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
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
Roadmapping Objectives
NANOfutures integrated
Roadmap aims to:
•
•
•
•
Industrial
and
Research
address European key nodes in terms of crosssectorial 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
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
NANOfutures is 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
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
Key
Nodes
Working
Group
ETP
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
Industrial Technologies 2012 Aarhus, 20 June 2012
Key
Nodes
Working
Group
ETP
Value
Chains
7 Value Chains were
identified by the
experts. The VCs
constitute the
backbone of the
roadmap
Industrial Technologies 2012 Aarhus, 20 June 2012
Key
Nodes
Value
Chains
Markets Several Markets
Working
Group
ETP
were outlined: the
WGs will analyze
them in order to
provide specific
guidelines for the
development of
nanotechnologies
Industrial Technologies 2012 Aarhus, 20 June 2012
NANOfutures Roadmapping
The loop is almost completed and will be the basis
for future activities of NANOfutures ETIP
Working
Groups
KeyNodes Leaders group
7 value chains and several
markets, that may use nanotech to
successfully address the economy
and society challenges
10 Horizontal
Working Groups
identified 5
KeyNodes based on
ETP’s needs
Working Groups
ETPs
Each market will be analyzed
and bottlenecks and missing
steps outlined, tracing the
roadmap to Horizon 2020
11 European Technology Platforms
described their needs
Industrial Technologies 2012 Aarhus, 20 June 2012
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.
Technological
Facilities
PULL
Science
Pilot
Lines
Technology
Products
Technological
Research
Production
MARKET
KNOWLEDGE
PUSH
Globally Competitive
Manufacturing Facilities
Industrial
Consortia
Competitive
Manufacturing
VALUE CHAIN
Industrial Technologies 2012 Aarhus, 20 June 2012
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.
TOOLS
METROLOGY
COMPONENTS
ASSEMBLY
MATERIALS
MODELLING
FINAL
PRODUCT
DESIGN
PRODUCT
PRODUCTION CHAIN
VALUE CHAIN
Industrial Technologies 2012 Aarhus, 20 June 2012
The Meaning of Value Chains
SAFETY
Sustainability overarch the chains
addressing the societal challenges.
EDUCATION
& TRAINING
STANDARDIZATION
ENVIRONMENT
COMMUNICATION
REGULATION
SUSTAINABILITY
GROWTH
SOCIETAL CHAIN
PRODUCTION CHAIN
VALUE CHAIN
Industrial Technologies 2012 Aarhus, 20 June 2012
The Meaning of Value Chains
Value chain actions are aligned with Horizon 2020 structure (Excellent
Science, Societal Challenges, Industrial Leadership).
Excellent
Science
KNOWLEDGE
DESIGN
GROWTH
Societal Challenges
Industrial
Leadership
MARKET
PRODUCTS
SUSTAINABILITY
VALUE CHAINS
Industrial Technologies 2012 Aarhus, 20 June 2012
Chains and Roadmap
SOCIETAL
CHAIN
PRODUCT
CHAIN
Cross-cutting actions that
overarch the roadmap
20 Possible Markets Identified
5 Key Nodes and 7 Value Chain
identified
MARKETs
PRODUCTs
SUSTAINABILITY
VALUE
CHAIN
The value chains constitute the backbone on
which is made the roadmap
KNOWLEDGE
DESIGN
GROWTH
The product chains bring the roadmap near to
the applicative and measurable field
The societal chains assure the sustainability
of the roadmap
Industrial Technologies 2012 Aarhus, 20 June 2012
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
Roadmap Overview
Value Chains
Functional Fluids
Lightweight multifunctional materials and
sustainable composites
Alloys Ceramics, Intermetallics
Structured Surfaces
Nano-enabled
surfaces
Nano-enabled surfaces for multi-sectorial
applications
Cross Sectorial Non-Technological Actions
Nano structures and
composites
Integration of nano
Infrastructure for Multiscale Modelling and
Testing
Nano-Micro scale
manufacturing
Design, Modelling and Testing
of materials
Key Nodes
Safety &
Sustainability
Industrial Technologies 2012 Aarhus, 20 June 2012
Roadmap Focus: VCs & Markets
VC1 - Lightweight
multifunctional materials
and sustainable
composites
Textile and sport
sector
VC3
Structured
Surfaces
Transportation
Packaging
Energy
Construction
and buildings
ICT
Construction and buildings
ICT (Nanoelectronics, photonics,
sensors)
Transportation
Textile and
passive funct.
Medicine
(Bio-sensors,
Lab on a
Chip, regen.
medicine)
Energy (PV
batteries,
harvesting)
VC5
Functional
Fluids
Construction and
building
Consumer
Products
(Cosmetics &
Household
Cleaning)
ICT (Thermal &
Electrical
Management)
Plasma and
Vacuum
Engineered
Surfaces
VC2 - Nanoenabled
surfaces for
multi-sectorial
applications
VC4
Alloys
Ceramics,
Intermetallics
Energy
Harvesting &
Conversion
ICT Functional
Packaging
Wet Engineered
Surfaces
VC7
Infrastructure
for Multiscale
Modelling and
Testing
Complex Adaptive
Systems for
complete product
design
VC6
Integration of
nano
Direct manufacturing
Transportation
Medicine &Pharma
Finished net shaped
3D structures for
nanoelectronics &
photonics
Catalysis
and
filtration
Cross Sectorial Non-Technological Actions
Semi
finished
Industrial Technologies 2012 Aarhus, 20 June 2012
Roadmap Focus: VCs & Markets
Markets
Value
Chains
Market 2
Each Market
meets many
ETP
ETPs
Market 3
Market 4
Market 1
Market 5
Each Market
Meets many
Societal
Challenges
Each ETP meets
many Societal
Challenges
EU societal challenges
Industrial Technologies 2012 Aarhus, 20 June 2012
Market &
Value Chain
ETPs
Industrial Technologies 2012 Aarhus, 20 June 2012
Roadmap Focus: VCs & Markets
VC1 - Lightweight multifunctional materials and sustainable composites
Construction and buildings
Textile and sport sector
VC2 - Nano-enabled surfaces for multisectorial applications
Plasma and Vacuum
Engineered Surfaces
Wet Engineered
Surfaces
Energy
Packaging
ICT
Transportation
VC4
Alloys Ceramics, Intermetallics
Energy Harvesting &
Conversion
ICT Functional Packaging
VC3 Structured Surfaces
Textile and
passive
funct.
Energy (PV
batteries,
harvesting)
Medicine (Biosensors, Lab on a
Chip regenerative
medicine)
Construction
and buildings
ICT (Nanoelectronics,
photonics, sensors)
Transportation
Industrial Technologies 2012 Aarhus, 20 June 2012
VC5 Functional Fluids
Consumer Products
(Cosmetics & Household
Cleaning)
Construction
and building
Medicine
&Pharma
ICT (Thermal &
Electrical
Management)
Transportation
VC6 Integration of nano
Direct
manufacturing
Finished net
shaped
3D structures for
nanoelectronics and
photonics
Catalysis and
filtration
Semi
finished
VC7 Infrastructure for Multiscale Modelling and Testing
Complex Adaptive Systems for
complete product design
Industrial Technologies 2012 Aarhus, 20 June 2012
ETPs
Direct answers
to the needs
Market &
Value Chain
Industrial Technologies 2012 Aarhus, 20 June 2012
ETP focus on specific VCs
VC2 - Nano-enabled
surfaces for multisectorial
applications
Plasma and Vacuum
Engineered Surfaces
VC6 Integration
of nano
VC3 Structured Surfaces
VC4
Alloys
Ceramics,
Intermetallics
Medicine (Bio-sensors, Lab on a Chip,
Regenerative medicine)
ICT Functional
Packaging
3D structures for
nanoelectronics and
photonics
ICT (Nanoelectronics, photonics,
sensors)
ICT (Thermal & Electrical Management)
Wet Engineered Surfaces
VC1 - Lightweight
multifunctional
materials and
sustainable
composites
VC4
Alloys Ceramics,
Intermetallics
Energy Harvesting &
Conversion
VC6 Integration of
nano
3D structures for
nanoelectronics and
photonics
Semi finished
VC3 Structured
Surfaces
VC6 Integration of nano
Medicine
3D structures for nanoelectronics and
photonics
(Bio-sensors, Lab on a
Chip, Regenerative
medicine)
VC5 Functional Fluids
Finished net
shaped
VC7 Infrastructure for
Multiscale Modelling
and Testing
Complex Adaptive
Systems for complete
product design
VC7 Multiscale
Modelling
Complex Adaptive
Systems for design
Cross
Sectorial
NonTechnologic
al Actions
Semi finished
Industrial Technologies 2012 Aarhus, 20 June 2012
VC4 Alloys Ceramics,
Intermetallics
ETP focus on specific VCs
VC1 - Lightweight
multifunctional
materials and
sustainable
composites
Construction and
buildings
Energy Harversting &
Conversion
VC6 Integration of
nano
VC3 Structured
Surfaces
VC5 Functional Fluids
Semi finished
Construction and
buildings
Construction and building
Catalysis and filtration
VC6 Integration of nano
Finished net
shaped
3D structures for nanoelectronics
and photonics
VC3 Structured
Surfaces
Medicine (Bio-sensors, Lab
on a Chip, Regenerative
Medicine)
VC1 - Lightweight
multifunctional materials and
sustainable composites
Textile and sport sector
VC5 Functional Fluids
Medicine &Pharma
VC3 Structured
Surfaces
Textile and passive
functionalities
Catalysis and
filtration
Semi
finished
Cross Sectorial NonTechnological Actions
VC7 Infrastructure for Multiscale
Modelling
Complex Adaptive Systems for complete
product design
Industrial Technologies 2012 Aarhus, 20 June 2012
VC3 Structured
ETP focus on specific
VCs
Surfaces
VC6 Integration of
nano
VC7 Infrastructure for Multiscale
Modelling
ICT (Nanoelectronics,
photonics, sensors)
3D structures for
nanoelectronics and
photonics
Complex Adaptive Systems for complete
product design
VC7 Infrastructure for Multiscale
Modelling
Complex Adaptive Systems for complete
product design
Cross Sectorial Non-Technological
Actions
VC1 - Lightweight
multifunctional materials and
sustainable composites
VC3 Structured
Surfaces
VC5 Functional
Fluids
Transportation
Transportation
Transportation
VC5 Functional Fluids
Consumer Products (Cosmetics &
Household Cleaning)
VC6 Integration of
nano
Catalysis and
filtration
VC7 Multiscale
Modelling
Complex Adaptive
Systems for complete
product design
Cross Sectorial
NonTechnological
Actions
Medicine &Pharma
VC2 - Nano-enabled surfaces for multi-sectorial applications
Plasma and Vacuum Engineered Surfaces
Wet Engineered
Industrial Technologies
2012Surfaces
Aarhus, 20 June
2012
ETPs
Direct answers
to the needs
EU societal
challenges
Industrial Technologies 2012 Aarhus, 20 June 2012
Societal Challenges focus
on specific VCs
Secure, clean and
efficient energy
Climate action,
resource efficiency
and raw materials;
Smart, green and
integrated transport
Some examples:
VC4
Alloys
Ceramics,
Intermetallics
VC1 - Lightweight
multifunctional materials
and sustainable
composite
Energy
Harvesting &
Conversion
Energy
VC6
Integration of
nano
…
Catalysis and
filtration
Transportation
VC7
Infrastructure
for Multiscale
Modelling and
Testing
VC3
Structured
Surfaces
Complex Adaptive
Systems for
complete product
design
Construction
and
buildings
VC4
Alloys
Ceramics,
Intermetallics
Energy
Harvesting &
Conversion
VC5
Functional
Fluids
VC1 - Lightweight
multifunctional materials and
sustainable composites
Transportation
Transportation
VC1 - Lightweight
multifunctional
materials and
sustainable
composites
Transportation
…
Industrial Technologies 2012 Aarhus, 20 June 2012
Societal Challenges focus
on specific VCs
Inclusive, innovative
and secure societies
VC4
Alloys
Ceramics,
Intermetallics
ICT Functional
Packaging
Food security, sustainable
agriculture, marine research
and the bio-economy
Some examples:
VC3 Structured
Surfaces
ICT (Nanoelectronics,
photonics, sensors)
VC3 Structured
Surfaces
VC1 - Lightweight
multifunctional materials
and sustainable
composites
Medicine (Bio-sensors,
Lab on a Chip, regen.
medicine)
Health, demographic
change and wellbeing;
Cross Sectorial
NonTechnological
Actions
VC5
Functional
Fluids
VC3 Structured
Surfaces
Consumer
Products
(Cosmetics &
Household
Cleaning)
Medicine (Bio-sensors,
Lab on a Chip, regen.
medicine)
…
…
Packaging
VC1 - Lightweight
multifunctional materials
and sustainable
composites
…
Textile and sport sector
Industrial Technologies 2012 Aarhus, 20 June 2012
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
Roadmap Overview
MATERIALS
MODELLING
METROLOGY
COMPONENTS
ASSEMBLY
FINAL
PRODUCT
WASTE
TREATMENT
TRL 1-4 TRL 5-6 TRL 7-8
TOOLS
MARKET DEFINITION
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
Roadmap Overview
TRL 1-4 TRL 5-6 TRL 7-8
TOOLS
MATERIALS
MODELLING
METROLOGY
MARKET DEFINITION
COMPONENTS
ASSEMBLY
FINAL
PRODUCT
WASTE
TREATMENT
ACTION
ACTION
ACTION
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
Roadmap Overview
TRL 1-4 TRL 5-6 TRL 7-8
TOOLS
MATERIALS
MODELLING
METROLOGY
MARKET DEFINITION
COMPONENTS
ASSEMBLY
FINAL
PRODUCT
WASTE
TREATMENT
ACTION
ACTION
ACTION
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
Roadmap Overview
The identified actions will address
two main outcomes in the roadmap:
The identification of common actions (technological
or not) from different markets and value chains.
The identification of markets and value chains that
require only few actions to be completed.
Industrial Technologies 2012 Aarhus, 20 June 2012