Transfer of technology from science to practice
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What are the
nanotechnologies
?
Transfer of
technology from
science to practice
Prof. Ing. Paolo Matteazzi
Chair of NANOfutures ETIP
President of MBN Nanomaterialia spa
MBN
What are the nanotechnologies ?
Transfer of technology from science to practice
Self cleaning surfaces,
High resistant cements
Pigments
Hip Joint from
Biocompatible
Plastics
Batteries,
lightweight
materials,
Catalytic
elements
Scratchproof
windows with
Self cleaning
lotus-effect
Intelligent/A
ctive
clothing
and tissues
LEDs save
Energy
Nano lithography
for processors
Reinforced
lightwight
frames
ALREADY
TRANSFERED
Cosmetics Additives
(Sun screens)
Food-Grade Additives
(Coffee foamer)
Brussels 09-2015
What are the nanotechnologies ?
Transfer of technology from science to practice
NANOTECHNOLOGY ALREADY IN INDUSTRY
Components for Industrial plant, Energy production,
Critical Raw Material substitution, Aerospace
Nanomaterials are classified under REACH. Therefore
manufacturers, importers and downstream users of
nanomaterials have to comply with the REACH
requirements.
Principal
Ktons/y
ear EU
Cabon Black
9500
Amorphous Silica
1500
Metal Oxides
350
CNT, Graphene, Fullerenes
0.3
NanoSilver
0.02
Brussels 09-2015
What are the nanotechnologies ?
Transfer of technology
from science to practice
Energy
NANOTECHNOLOGIES
Chemical
Sport
Telecomunications
Computer/Data storage
Constructions
Transportation
Health Care / Pharma.
Biotechnologies
Aerospace / Defence
Nanotechnologies are horizontalenabling convergent technologies
which cross all vertical industrial
sectors.
• They are ‘horizontal’ because they cut across
numerous industrial sectors;
• They are ‘enabling’ since they provide the
platform, the tools to realise certain products;
• They are ‘convergent’ because they bring
together sectors of science that were
previously separated
NANOfutures Platform
has been shaped
accordingly
Agriculture & Food
Brussels 09-2015
NANOfutures EITP
NANOfutures
is
an
European
Integration and Innovation Platform of
which main objective is to facilitate the
nanotechnology development and
commercialization by connecting all
relevant nanotechnology stakeholders
NANOfutures
association
Stakeholders: European Technology Platforms, Industries, Research
Institutions, Universities, Associations, Regional and National clusters
It addresses cross-sectorial needs, joining the efforts of all the stakeholders;
It aims at meeting grand societal and economical challenges through fostering
the relevant of sustainable nano-enabled products
It aims at reducing fragmentation, aligning research and innovation efforts
for the competitivenes of European nanotechnology
Brussels 09-2015
NANOfutures EITP
INDUSTRIALIZATION
>1000 Members
RESEARCH and TECH.
SAFETY
STANDARDIZATION
REGULATION
COMMUNICATION
The Platform structure guarantees a cross-cutting approach:
-10 Horizontal Working Group -11 ETP representatives
Tech.Transfer and
Innovation Financing
NETWORKING
SKILLS AND EDUCATION
CRITICAL ROW
MATERIALS
Brussels 09-2015
NANOfutures Roadmaps
2012
2015
Actions for Value Chains development
Enabling products in different industrial sectors
Converging on common key issues
Brussels 09-2015
Roadmap Focus: VCs & Markets
VC1 - Lightweight
multifunctional materials
and sustainable composites
Textile and
sport sector
VC3
Structured
Surfaces
Textile
Textile
and
and
passive
passive
funct.
funct.
VC5
Functional
Fluids
Household
Household
Cleaning
Cleaning
Cosmetics
Cosmetics
Energy
Transportation
Packaging
Packaging
ICT
Construction
Construction and buildings
buildings
ICT (Nanoelectronics, photonics)
Transportation
Energy
PV
Energy (PV
batteries,
batteries,
harvesting
harvesting))
Construction
and building
Transportation
Medicine
Medicine
&Pharma
&Pharma
Medicine
(Bio-sensors,
regen.
medicine)
VC2 - Nanoenabled
surfaces for
multi-sectorial
applications
VC4
Alloys
Ceramics,
Intermetallics
Energy
Energy
Harvesting
Harvesting &&
Conversion
Conversion
Direct manufacturing
Finished net shaped
3d structures for
optoelectronic
Plasma and
Vacuum
Engineered
Surfaces
Wet
Wet Engineered
Engineered
Surfaces
Surfaces
VC7
Infrastructure
for Multiscale
Modelling and
Testing
Complex Adaptive
Systems for
complete product
design
VC6
Integration of
nano
Catalysis
Catalysis
and
filtration
filtration
Semi
finished
WHERE IS THE CHEMICAL INDUSTRY?
Brussels 09-2015
Roadmap Focus: VCs & Markets
NANOfutures roadmaps consider the whole Value Chain : looked
to the production chain to find the gap and define the actions that
are present in the roadmap, prioritizing them according to the TRL
MARKET
There are also subsidiary
production/supply chain that
complete the development scenario
Basic R&D,
Knowledge
Assembly
Materials
Tools
Product
Brussels 09-2015
9
The complex structure of the whole
value chain reflects the complexity
of real problems.
A production chain that do not
arrive to a final product does not
create a real economic growth.
8
7
6
5
4
3
2
1
0
Modeling
Raw
Meterial
Processing
Metrology
Final product
Material
delivered
Assembly
Components
Material
Brussels 09-2015
The complex structure of the whole
value chain reflects the complexity of
real problems.
A production chain that do not
arrive to a final product does not
create a real economic growth.
9
8
7
6
5
4
3
FINAL PRODUCT
AT PILOT LEVEL
2
1
0
Modeling
Raw
Meterial
Processing
Metrology
Final product
Material
delivered
Assembly
Components
Material
The focus is in
providing the support
to increase the whole
cube in up to TRL 9, or
to TRL7 for the
corresponding
pilot line
Brussels 09-2015
Focusing on the
technological GAPs is not
enough to arrive at the
end with a sustainable
product
9
8
7
6
5
4
The framework
needs to be
expanded also to
nontechnological
actions
3
2
1
0
Modeling
Raw
Meterial
Processing
Metrology
Final product
Material
delivered
Assembly
Components
Material
Brussels 09-2015
EXAMPLE of Value Chain
VC1 - Lightweight
multifunctional materials
and sustainable composites
Textile and
sport sector
VC3
Structured
Surfaces
Textile
Textile
and
and
passive
passive
funct.
funct.
VC5
Functional
Fluids
Household
Household
Cleaning
Cleaning
Cosmetics
Cosmetics
Energy
NANOFUTURES ROADMAP
Transportation
Packaging
ICT
Construction
Construction and buildings
buildings
ICT (Nanoelectronics, photonics)
Transportation
Energy
PV
Energy (PV
batteries,
batteries,
harvesting
harvesting))
Construction
and building
Transportation
Medicine
Medicine
&Pharma
&Pharma
Medicine
(Bio-sensors,
regen.
medicine)
VC2 - Nanoenabled
surfaces for
multi-sectorial
applications
VC4
Alloys
Ceramics,
Intermetallics
Energy
Energy
Harvesting
Harvesting &&
Conversion
Conversion
Direct manufacturing
Finished net shaped
3d structures for
optoelectronic
Plasma and
Vacuum
Engineered
Surfaces
Wet
Wet Engineered
Engineered
Surfaces
Surfaces
VC7
Infrastructure
for Multiscale
Modelling and
Testing
Complex Adaptive
Systems for
complete product
design
VC6
Integration of
nano
Catalysis
Catalysis
and
filtration
filtration
Semi
finished
WHERE IS THE CHEMICAL INDUSTRY?
Brussels 09-2015
EXAMPLE of Value Chain
Catalyzed Esterification and
Trans-esterification
Filtering,
Classification
Byproduct
Separation
PRODUCT:
BIODISEL FROM
WASTE
COOKING OIL
Nanoparticles Engineering
for Stable catalyzer
Nanoparticles Production,
tools and techniques
Gathering Waste
Cooking Oil
Raw precursors
Most of these steps are not
specifically related only to
the Chemical Industry
Catalysis
and
filtration
Brussels 09-2015
EXAMPLE of Value Chain
PRODUCT:
BIODISEL FROM
WASTE
COOKING OIL
Roadmap Actions
Calls
Colloidal chemistry, micells, source
NMBP 01-2016: Novel hybrid
Nanoparticles Engineering
nanomaterials Coatings, self assembling,
materials for heterogeneous catalysis
for Stable catalyzer
Filtering,
etching, sintering
Classification
Characterise and control potential release of
NMP 3 – 2015: Manufacturing and
particles during manufacture and transport of
control of nanoporous
materials
Nanoparticles
Production,
materials. Understand the hazardous nature of
tools and techniques
these materials
Gathering Waste
Design ofOil
material architectures
NMP.2013.1.1-1 Exploration,
Cooking
for unbounded properties
optimisation
and control of nanoRaw precursors
catalytic processes for energy
applications
Large scale, low cost source of nanomaterials
{Obtained by Friction, Plastic deformation,
Supercool laser, Self-assembly/ phase
separation (organic), In situ crystallization}
Catalysis
and
filtration
Brussels 09-2015
What are the nanotechnologies ?
Transfer of technology from science to practice
Nanotechnology transfer from science to
practice should be shaped accordingly
The Nanotechnologies are
HORIZONTAL
Targeting industrial needs of the different
sectors, even for industries that do not
seek for nano-solutions
ENABLING
Heading to a product,
CONVERGENT
Research, Safety, Regulation,
Standardization, should follow a common
plan to avoid dispersion of effort
Brussels 09-2015
THANK YOU FOR YOUR ATTENTION
FIND THE ON LINE ROADMAP DOCUMENTS:
-“Implementation Roadmap on value chains
and related pilot lines”
-“Appendix to the Implementation Roadmap
on value chains and related pilot lines” at:
http://nanofutures.eu/documents
Please, join our Open Consultation at:
http://value4nano.eu
Brussels 09-2015
