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PV-TEC: PHOTOVOLTAIC TECHNOLOGY EVALUATION CENTER
F R A U N H O F E R I N S T I T U T E F O R S O l A R E N E R g y S y S T E m S I S E
www.pvtec.de
www.pv-training.org
Fraunhofer Institute for
Solar Energy Systems ISE
Heidenhofstrasse 2
79110 Freiburg
Germany
Phone +49 761 4588-0
Fax +49 761 4588-9000
www.ise.fraunhofer.de
PV Production Technology and Quality Assurance
Dr Ralf Preu
Phone +49 (0) 761/4588-5260
info@pvtec.de
Thermal, PVD and Printing Technology/
Industrial Cell Structures
Dr Daniel Biro
Phone +49 (0) 761/4588-5246
info@pvtec.de
Wet Chemical and Plasma Technologies/
Cell Process Transfer
Dr Jochen Rentsch
Phone +49 (0) 761/4588-5199
info@pvtec.de
Inline measurement Techniques and
laser Process Technologies/Quality Assurance
Dr Stefan Rein
Phone +49 (0) 761/4588-5271
info@pvtec.de
1 Quantitative photoluminescence imaging of solar cells: dark
saturation current image (left) and series resistance image (right).
2 Automated IV-curve, electroluminescence and thermography
measurement at PV-TEC.
Characterization and material Evaluation
The technological work is accompanied by comprehensive
analysis and qualification of silicon materials and solar cells
which enable efficiency-limiting mechanisms to be
identified and material, processes and cell concepts to be
systematically improved. Using a large variety of state-of-
the-art offline and inline metrology systems, we are able to
measure all relevant quality parameters on starting wafers,
solar cell precursors and finished solar cells on a statistically
relevant basis. Metrology systems with high spatial resolution
allow loss mechanisms of cells to be analyzed in depth. A
well-equipped wet-chemistry analysis laboratory allows inline-
monitoring of chemical baths.
metrology Evaluation
PV-TEC provides excellent conditions for qualifying new
measuring instruments from manufacturers for use in PV
industry. Measurement suitability testing can be performed
on any form of test samples, measurement accuracy can be
determined by numerous reference methods and reliability
and reproducibility may be tested by temporarily incorporating
inline measuring systems into automatic measuring stations.
metrology Development, Data Analysis and Simulation
We develop metrology, data analysis and simulation tools in
various areas, both independently and with partners. A major
focal point lies in electro- and photoluminescence imaging
where we develop inline-capable image recording methods for
contrast differentiation and quantitative determination of phys-
ical parameters, image processing algorithms for automated
identification of process and material defects and complete
wafer rating models for a performance prediction based on
raw-wafer data, which can be adapted to customer processes.
Finally, we also develop simulation tools to analyze efficiency
potential and loss mechanisms of the developed cell concepts
as well as their sensitivity towards process variations.
Characterization of New Silicon materials
We analyze all wafer-based silicon materials from standard
and alternative feedstock such as upgraded metallurgical
grade and compensated silicon, standard and high-
performance multi and mono-crystalline silicon, with respect
to the efficiency-limiting electrical characteristics such as
recombination lifetime, impurity content and crystallographic
structure taking into account block position. We develop
adapted processes for material improvement and determine
the efficiency potential on adequate statistical basis.
Wet Chemistry Analysis
We develop volumetric, chromatographic and spectroscopic
methods for an automated determination of concentrations
in chemical baths to enable in-situ observation of etching
systems and systematic development of etching, texturization
and cleaning processes.
Cover photo: Automated loader for a
tube diffusion furnace combined with
inline metrology at PV-TEC.
1 2
PV TRAININg
In cooperation with the PSE AG we offer training courses
covering topics throughout the entire PV value chain on
engineering and decision maker level. Already more than
600 persons have been trained at PV-TEC.
More information is available on our web site.
www.pv-training.org
PTQ-0416
Production Technology Research
Since its foundation in 1981 Fraunhofer ISE conducts R&D in
the field of photovoltaics (PV) and since 1996 in the field of PV
production technology. The main objectives are an increase of
efficiency and a reduction of process cost based on advanced
cell concepts, highly productive processes and materials and a
more efficient use of resources.
In 2005 the Photovoltaic Technology Evaluation Center
(PV-TEC) was set up with a basic investment of 12 Mio. Euro
mainly covered by the German Ministry of the Environment
to support the German / European PV industry, enabling solar
cell processing and characterization on a level of several 100
wafers/hour. Inaugurated in 2006, our Photovoltaic Techno-
logy Evaluation Center PV-TEC was the first non-profit R&D
laboratory in the field of crystalline silicon solar cells based on
large scale and mostly automated equipment. Since then more
than 4000 extensive experiments have been conducted and
the infrastructure has been continuously improved to match
the demand on cutting edge pilot technology.
In 2016 PV-TEC was augmented by PV-TEC Select to allow
front end processing which is very sensitive to contamination,
such as cell structures based on selective contacts (e.g. hetero-
junction solar cells). A cleanroom area of 800 m² (cleanroom
class 1000) enables large scale research and development
targeting highest conversion efficiency.
We offer customized services to:
n solar cell, module and silicon wafer manufacturers
n equipment vendors
n process material suppliers
1 Industrial inline processing tool for acidic
texturing and single side etching applications (PV-TEC).
2 Automated tube furnace in PV-TEC with
inline characterization instruments.
AREAS OF SERVICE
ndevelopment and evaluation of processes and
characterization as well as equipment thereof,
including technical and economic parameters
n design and realization of advanced solar cell structures
n characterization and evaluation of materials and cells
n technology assessment
n evaluation and improvement of production lines
n training for PV companies
n process transfer / in-house support
Development and Evaluation of Processes and Equipment
laboratories
To conduct our research we operate various laboratories with
state-of-the-art equipment and metrology instruments,
covering a total of more than 2.500 m² of high quality lab
space in 2016. The PV-TEC industrial R&D platform features
mostly automated equipment ready for large scale and
complex experiments. We have developed an information
technology based quality management system which allows
the constant control of the quality and improvement of our
experiments and underlying technology.
Technology
PV-TEC features industrially relevant production technology
needed for advanced solar cell processing of silicon wafers of
standard and specific sizes (on request) including:
n wet chemical etching, cleaning and conditioning
(texturing, single side etching, industrial cleaning
sequences, tunnel oxide formation); Inline and batch
systems on industrial scale but also smaller wet benches
n chemical vapor deposition, diffusion, oxidation and
annealing: POCl3 and BBr3 diffusion, dry and wet thermal
oxidation and annealing (thermal donor activation,
pre-gettering, post-implantation) in tube furnace;
diffusion, oxidation and annealing in inline furnace
n thick-film printing: screen, stencil printing and dispensing
of metal, polymer, dielectric, dopant and etchant pastes;
high precision automated and semi-automated screen
printing and dispensing tools (single and highly parallel
multinozzle equipment)
n dry conditioning and etching: plasma and atmospheric
processing and tools
n PVD (Physical Vapor Deposition): sputtering of dielectric
and transparent conduction oxide layers, inline sputtering
and evaporation of metal layers and metal stacks both for
front and rear contacts of solar cells
n inkjet printing and structuring: etchant polymer, dielectric,
metal and other inks can be printed on various platforms
n PECVD (Plasma Enhanced Chemical Vapor Deposition):
coating with various AR (anti-reflection) and passivation
layers in automated and manual direct and remote
plasma systems
n laser processing: ablation (local contact opening LCO),
doping (selective emitter formation), alloying (laser fired
contacts LFC, foil metallization) laser-assisted transfer of
metals and dopants, annealing and regeneration; various
high quality automated and manual laser workstations,
optical bench for laser testing
Printed Process materials and Development of Printing
machine Components
Printed materials can be applied in solar cell fabrication for
various purposes, mainly:
n metallization (Ag, Al, Cu and other electrical conductors)
n pn-junction formation, structuring (p-, n-type) and
diffusion barriers – based on different materials
n structuring of silicon, dielectrics and metal layers
n surface coating for optical and for passivation purposes
n isolation (e.g. solderstop materials)
We do process development as well as scale-up and we sup-
port the development of machine components to suit special
material properties. We offer extensive CFD (Computational
Fluid Dynamics) simulation know-how, to support quick
machine parts design.
PATENTS AND lICENCES
We hold and file patents on our research, thus protecting
the generated intellectual property (IP) together with our
patent experts. Licenses can be granted for various patents
to allow a safe market entry.
CONFIDENTIAlITy
A very high degree of confidentiality is of paramount
importance. On request, all correspondence and
cooperation results can be covered by NDAs to protect
customer interests.
Design and Evaluation of Advanced Solar Cell Structures
We develop and offer technology to process a wide range
of advanced cell structures. Additionally we use and offer
support for the modelling of such cell structures and structural
elements based on single and multi-dimensional finite element
simulation and analytic calculation tools.
Passivated Emitter and Rear Solar Cells
For the development of p- and n-type solar cells with passivat-
ed surfaces and localized contacts we develop both individual
technological components and completed process sequences:
n single side treatment processes for cleaning and
passivation
n laser treatment for locally contacted rear surface
n advanced junction formation and selective doping
structures, co-diffusion for simultaneous p- and n-doping
n passivation based on vacuum deposition (aluminum oxide,
silicon nitride and customized stacks)
n passivation based thermal oxidation
(wet and dry processes)
n metallization for advanced front and rear contacts
n process and concept developments for bifacial application
n regeneration processes to eliminate light-induced
degradation in Cz-Si and mc-Si
n process developments suitable for thin wafers
CEll STRUCTURES DEVElOPED AT PV-TEC
n standard H-patterned Al-BSF solar cells
n industrial passivated emitter and rear solar cells based
on p- and n-type silicon wafers
n MWT and MWT-PERC solar cells
n back junction solar cells
n heterojunction solar cells
n thin and ultrathin solar cells
n bifacial solar cells
n one-sun, low illumination and concentration
applications
1 2 3 4
Back Contact Solar Cells
Back contact solar cell structures enable increased efficiency
and module design. We develop and transfer technology for
n standard size metal wrap through (MWT) cells which can
be combined with passivated surfaces
n modular MWT cell design (all-purpose MWT) for low
concentration application (around 10x) but also for low
light applications (indoor etc.)
n back-contact back-junction (BC-BJ) without any front
contacts which allow very high efficiencies
Carrier Selective Solar Cell Structures
We conduct process and equipment evaluation as well as
material characterization to optimize solar cells with carrier
selective surfaces (i.e. heterojunction (HJT), poly-Si based
structures) in order to reduce the production cost of these
high efficiency cell structures. We feature very low contamina-
tion conditions for front-end processes in PV-TEC Select
(clean room class 1000):
n simplified cleaning and surface conditioning prior to
intrinsic amorphous silicon deposition
n inline deposition of intrinsic and doped a-Si layers on
various technology platforms
n tunnel oxide formation
n LPCVD (low pressure chemical vapor deposition) of intrinsic
and doped poly-Si layers
n alternative TCO deposition techniques and materials
n fine line metallization of low temperature pastes based
on screen printing, dispensing and inkjet techniques
n inline PVD deposition of metal stacks for rear side
metallization
Further cell structures are under development.
3 High speed laser drilling process.
4 In the rear contacted MWT solar cell metallized vias conduct the
electrical current to the rear surface.
Process Transfer
Beside the in-house development, we also offer to transfer in-
dividual PV-TEC processes or complete process sequences into
the industrial process lines of our customers. The transfers are
accomplished by detailed process descriptions and customer
site support during process start-up.
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