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Center for Advanced Technologies
POMERANIA
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Definition (MNiI)
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Center for Advanced Technologies is a consortium
composed of scientific units performing research at the
international level, and other units promoting and
interested in scientific research, development
innovations and commercialisation.
The consortium partners can, based on mutual
agreement, perform the interdisciplinary tasks focused
on elaboration, development and commercialisation of
new technologies associated with science fields
assumed as the extremely important for national
economy concerning the scientific and innovation policy.
KSI
CTT
UNIWERSYTET
USTRZYCKI
AKADEMIA
USTRZYCKA
FIRMA
SUPER
KOMPTER
ERA
NoE
CENTRUM
SZKOLEŃ
CoE
CoE
LAB3
LAB1
LAB2
PRE
INK
PRE
INK
INKUBATOR
PARK
NAUKOWOTECHNOLOGICZNY
PRZEDSIĘBIORSTWA
LAB4
Strategy
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Analysis of the current state
Mission
Strategic activity axes
Main objectives
Milestones
Specific objectives
Main tasks
Outcomes
Relation between CAT and Regional Innovation
Strategy
Mission
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Joint actions of all partners for creation of
advanced technologies at the preindustrial technologies and enhancement
of their transfer to an industry to satisfy
the market demands.
Strategic activity axes
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Biotechnology
Functional materials
Environment protection
ICT
Main objectives
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Applied research
Development of advanced technologies
Enhancement of commercialisation (preindustrial stage)
Main tasks
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Foundation of research and technological infrastructure
Generation of multipartner projects
Development of advanced technologies
Intelectual property protection
Technical advising
Enhancement of formation of excellence and competence
centers, trnsfer technology centers, specialistic laboratories
and small enterprises, new workplaces
Exploration of potential application areas
Collection and dissemination of information
Promotion and marketing
Education
Outcomes
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Pre-industrial technologies
Joint research and investment projects
Industrial cooperation agreements
Entrepreneurs contacted the CAT (CZT)
???
The project „Center of
Advanced Technologies
POMERANIA”
financed by the E.U.
structural funds:
the Regional Operational
Programme of the
Pomerania Voyevodship
(6 Mln EURO)
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CAT Pomerania - foundation: 2000 r.
28 partners (universities and enterprises)
Coordinating partner: Gdansk University of
Technology
R&D
Domains
Biotechnol
ogy & food
and drugs
chemistry
Information
technologies
&
telecommuni
cations
Functional
materials &
nanotechnolo
-gies
Environme
nt
protection
Biotechnology, food and drugs
chemistry
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Baltic Center of Biotechnology and
Innovative Diagnostics
Information technologies and
telecommunications
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Civitronics Center
Laboratory of Metrology and Information
Systems
Environmental Laboratory of Wireless
Technologies
A great number of industrial partnerships
and agreements
ICT Cluster
Environment protection
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Mobile Laboratory of Environment
Diagnostics and Protection
Ecology Cluster
Functional materials and
nanotechnologies (MATECH)
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Laboratory of Nanomaterials
Laboratory of Biomaterials
Laboratory of Syntesis of Innovative Materials and
Elements
Laboratory of Optoelectronic Measurements of
Innovative Materials and Displays
Laboratory of Polymers
Laboratory of Nanomaterials and Nanocomposites
Laboratory of Characterisation of Luminescent Materials
and Nanomaterials
MATECH
Gdansk University of Technology:
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Dep. Materials Science and Engineering,
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Dep. Optoelectronics,
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Dep. Chemical Technology,
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Dep. Technology of Polymers,
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Dep. Physical Chemistry,
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Dep. Solid Staste Physics,
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Dep. Physics and Electronic Phenomena,
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Dep. Materials Engineering, Corrosion and Electrochemistry
Gdansk University:
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Dep. Chemical Technology,
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Dep. Organic Chemistry,
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Dep. Supramolecular Chemistry,
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Dep. Condensed Phase Spectroscopy
Gdynia Maritime Academy:
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Dep. Ship Materials and Repair Technology
Ship Design and Research Center:
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Dep. Materials Science, Corrosion and Environment Protection
Outcomes
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11 laboratories supported by the CZT Project (A. Zieliński –
chairman)
A number of joint industrial or industry-oriented project
Center of Knowledge and Entrepreneurship
Regional Transfer Technology Center
Academic and Student Entrepreneurship Incubators
Education and information
Information and promotion
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Webpage of the project
Mass media
Seminars and workshops
Education
Technical Information Fast Service (TIFS)
Next phase: Clusters
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Biobaltica Center
Ecology Center
Biotechnology Center
ICT Cluster
Energy Power and Conversion Center
Bioengineering Center
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Partners:
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GUT (WM – 5 departments, WETI< WCh, WFTiMS)
GMA
Implant producers (Medgal, Eskulap et al..)
Financing:
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Bioengineering Center
Polish-Icelandic ERA-NET MATERA project
Application within the Polish - Swiss Research Programme
Application for numerous national projects
Industrial cooperation (Norwich holding)
International cooperation:
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Germany,
Iceland,
Italy,
Swiss,
Spain,
Portugal,
Great Britain,
Bulgarien
Advanced technologies
Fabrication technologies of bioactive
titanium implants
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Powder metallurgy and
rapid prototyping
(Selective Laser Melting)
Composite bioactive
metal-ceramic-polymer
porous implants filled in
with biodegradable core
material
Advantages: more
comfort, longer lifetime
Technologies for superhard layers
for specialty alloys
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Multiplex layers of very high hardness,
corrosion resistance, biocompatibility for
tools and implants
Nanomodification of surface layers on
elements made of nonferrous alloys
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Cryogenic laser tretament
is applied for Cu and Al.
Alloys allowing the
increase in hardness,
corrosion resistacne,
tribological and
tribocorrosion resistance
Technology applicable for
Diesel engines and ship
propellers
CVD technology for thin carbon,
diamond-like-carbon and diamond
structures
For hardening of
optical,
mechanical,
mechatronical
systems
Liquid crystalline polymers
For surfaces of glassy
optical elements.
Wyciąg
Lampa UV
Podłoże
szklane
Wirówka
Fabrication technologies
of luminescent materials
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Applications
-Low energy
batteries
-Luminophores and
LED lamps
-X-ray screens
-Components of
lighting paints
Fabrication technologies
of luminescent materials
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Synthesis of powder
metallurgy produced
oxide materials dopped
with some rare earth
and transient metals.
Fabrication technology of oxidenitride aerogels
Better in mechanical
strength and thermnal
resisance than
conventional SiO2
aerogels.
For thermoinsulating
materials of improved
mechanical strength
Ceramic materials
for oxide fuel cells
•Advanced fabrication
technologies of planar
ceramic fuel cells for
moderate temperatures
(IT-SOFC)
katoda
anoda
Superconductivity ceramics for energy
supplies
Fabrication technologies
of YBaCuO and
BiSrCaCuO
[Nature 414(2001)368]
Magnetic nondestructive tests of degradation
of metallic constructions
Original tests:
•
• intrinsic stresses by Barkhausen effect
Zasada badania za pomocą
elektromagnesu jarzmowego:
1 – detektor EMA, 2 – detektor HEB,
3 – smar, 4 – jarzmo
•degradation degree of materials operating under
conditions of varying stresses and temperatures by
magnetoacoustic emission and eddy currents
•disconituities by measurement of dispersed magnetic field
and bu an use of magnetostrictive pulses
Advanced polymers
•.
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Fabrication technologies of materials
composed of PU and recyclates from garbage
of polymers and rubber.
Fabrication technologies of PU technical goods
for extremely conditions and for households.
Polyurethanes (PU) and PU-based composite
and nanocomposite materials.
Syntethic molecular receptors
for diagnostics and nanotechnologies
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Sensors for
analitycs
Optical chemical sensors
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For medicine and in
environment protection
to recognise e.g.
copper and lead.
Chemosensor is an
element deposited on
mesoporous ceramics.
It is insoluble.
To enhance the
sensibility, the silver or
gold nanostructures are
applied.
90
80
Emission intensityI / arb.units
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70
(b)
60
50
40
(a)
30
20
10
0
1E-4
1E-3
Concentration Cu(II) / log c
0.01
Luminescent materials as an alternative light
source
J= 5
500

E m is s io n
542
55 0
50 0
400
45 0
224 nm
383
300
6
E m is s io n in te n s ity I / a .u .
Proposed luminescent
materials are composed of
oxide xerogels and optically
active components
They are fotochemically more
stable than so far used
materials even at higher
temperatures.
In t e n s it y I / a r b . u n it s

E x c ita tio n
40 0
35 0
30 0
25 0
20 0
15 0
10 0
0
20 0
40 0
6 00
80 0
10 00
o
T e m p e ratu re t / C
200
4
(a )
3
268
100
(b )
0
200
300
400
500
600
700
W a v e le n g th  / n m
800
900
Thank you for your attention
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