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This PDF file contains the front matter associated with SPIE Proceedings Volume 7921, including the Title Page, Copyright information, Table of Contents, Introduction, and the Conference Committee listing.
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A new method to fabricate microstructures built by polymer microparticles using a bottom-up technique is presented.
The microstructures find broad application in micro-fluidics technology, photonics and tissue-engineering. The handling
of the particles is realized by a holographic optical tweezers setup, ensuring the precise allocation of the particles to the
desired structure. A biochemical technique ensures that the structure remains stable independent of the laser source. We
show that with this method complex two-dimensional durable structures can be assembled and cannot be separated by
optical forces. The structures are extendable during the entire fabrication process and can be linked to further particles
and structures as desired.
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Digital microfabrication processes are non-lithographic techniques ideally capable of directly generating patterns and
structures of functional materials for the rapid prototyping of electronic, optical and sensor devices. Laser Direct-Write
is an example of digital microfabrication that offers unique advantages and capabilities. A key advantage of laser directwrite
techniques is their compatibility with a wide range of materials, surface chemistries and surface morphologies.
These processes have been demonstrated in the fabrication of a wide variety of microelectronic elements such as
interconnects, passives, antennas, sensors, power sources and embedded circuits. Recently, a novel laser direct-write
technique able to digitally microfabricate thin film-like structures has been developed at the Naval Research Laboratory.
This technique, known as Laser Decal Transfer, is capable of generating patterns with excellent lateral resolution and
thickness uniformity using high viscosity metallic nano-inks. The high degree of control in size and shape achievable has
been applied to the digital microfabrication of 3-dimensional stacked assemblies, MEMS-like structures and freestanding
interconnects. Overall, laser forward transfer is perhaps the most flexible digital microfabrication process
available in terms of materials versatility, substrate compatibility and range of speed, scale and resolution. This paper
will describe the unique advantages and capabilities of laser decal transfer, discuss its applications and explore its role in
the future of digital microfabrication.
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The studies toward the formation of Si and Ge films and micropatterns by wet process using laser direct writing method
are reported. First is the the formation of Si film by laser scanning irradiation to Si nano- or micro-particle dispersed
films. By using organogermanium nanocluster (OrGe) as a dispersion medium of Si particles, a homogeneous Si film
was formed by laser scanning irradiation on a Si particle/OrGe composite film. The micro-Raman spectra showed the
formation of the polycrystalline Ge and SiGe alloy during the fusion of the Si particles by laser irradiation. The second
is the formation of the Si and Ge micropatterns by LLDW (liquid phase laser direct writing) method. Micro-Raman
spectra showed the formation of polycrystalline Si and Ge micropatterns by laser irradiation on the interfaces of
SiCl4/substrate and GeCl4/substrate, respectively.
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Plastics play an important role in almost every facet of our lives and constitute a wide variety of products, from everyday
products such as food and beverage packaging, over furniture and building materials to high tech products in the
automotive, electronics, aerospace, white goods, medical and other sectors [1].
The objective of PolyBright, the European Research project on laser polymer welding, is to provide high speed and
flexible laser manufacturing technology and expand the limits of current plastic part assembly. New laser polymer
joining processes for optimized thermal management in combination with adapted wavelengths will provide higher
quality, high processing speed up to 1 m/s and robust manufacturing processes at lower costs. Key innovations of the
PolyBright project are fibre lasers with high powers up to 500 W, high speed scanning and flexible beam manipulation
systems for simultaneous welding and high-resolution welding, such as dynamic masks and multi kHz scanning heads.
With this initial step, PolyBright will break new paths in processing of advanced plastic products overcoming the quality
and speed limitations of conventional plastic part assembly. Completely new concepts for high speed processing,
flexibility and quality need to be established in combination with high brilliance lasers and related equipment.
PolyBright will thus open new markets for laser systems with a short term potential of over several 100 laser
installations per year and a future much larger market share in the still growing plastic market. PolyBright will hence
establish a comprehensive and sustainable development activity on new high brilliance lasers that will strengthen the
laser system industry.
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Oxide and non oxide ceramics (Al2O3, SiC) were brazed to commercial steel with active filler alloys using a CO2-laser
(l = 10.64 μm). Two different laser intensity profiles were used for heating up the compound: A laser output beam
presenting a Gaussian profile and a homogenized, nearly top head profile were applied for joining the compounds in an
Argon stream.
The temperature distribution with and without the homogenizing optic was measured during the process and compared to
the results of a finite element model simulating the brazing process with the different laser intensity profiles. Polished
microsections were prepared for characterization of the different joints by scanning electron micrographs and EDXanalysis.
In order to evaluate the effects of the different laser intensity profiles on the compound, the shear strengths of
the braze-joints were determined. Additionally residual stresses which were caused by the gradient of thermal expansion
between ceramic and metal were determined by finite element modeling.
The microsections did not exhibit differences between the joints, which were brazed with different laser profiles.
However the shear tests proved, that an explicit increase of compound strength up to 34 MPa of the ceramic/metal joints
can be achieved with the top head profile, whereas the joints brazed with the Gaussian profile achieved only shear
strength values of 24 MPa. Finally tribological pin-on-disc tests proved the capability of the laser brazed joints with
regard to the application conditions.
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Joining of similar or dissimilar materials with a thickness in the range of micrometers and sub micrometers is of
great interest for a number of applications in, e.g., micro technology, photovoltaic and thin-film technology. A
laser micro joining process using 25 ns long KrF excimer laser pulses for joining thin films and foils is
demonstrated. Metal films of silver, aluminium, copper, molybdenum and titanium with thicknesses down to
500 nm deposited on polyimide substrates were used for bonding to a 12.5 μm thick silver foil. The laser
fluencies used for joining of the foil to the metal films are in the range of 3.5 J/cm2. The laser-induced joints
were investigated by SEM (scanning electron microscope), optical microscopy, and a tensile strength tester.
The shear stress calculated from the tensile force measurements and considering the laser-exposed area to be the
bonding area is 0.5 N/mm2 for silver/aluminium bonds. The tensile strength is not only determined by the bond
between the metal films but also by the adhesion of the thin film to the substrate. Synergetic effects lead to bond
formation comprising of thermal, mechanical, and chemical processes.
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Laser welding is a commonly used process to assemble medical devices. The heat produced during the laser welding
process may have an adverse effect on the mechanical integrity of the case assembly and the functionality of heat
sensitive electronic components. In order to maintain the mechanical integrity of the case assembly and to protect the
subcomponents, it is important to control the temperature in the assembling process, the investigation of the temperature
distribution in the assembly during laser welding is thus necessary. In this paper, we report an experimental method and
a numerical simulation for the investigation of the temperature field in the process of laser welding the eyelet to the case
subassembly of the Functional Electrical Battery Powered Microstimulator (FEBPM). A pulsed 1064nm Nd:YAG laser
is used as an example in this paper.
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Additive Manufacturing and Advanced Deposition Processes
To up-grade selective laser melting (SLM) process for manufacturing real components, high mechanical properties of
final product must be achieved. The properties of a part produced by SLM technology depend strongly on the properties
of each single track and each single layer. In this study, effects of the processing parameters such as laser power,
scanning speed and powder layer thickness on the single tracks formation are analyzed. It is shown that, by choosing an
optimal technological window and appropriate strategy of SLM, it is possible to manufacture highly complex parts with
mechanical properties comparable to those of wrought material.
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Temperature monitoring in the laser impact zone is carried out by an originally developed bi-colour pyrometer which is
integrated with the optical scanning system of the PHENIX PM-100 machine.
Experiments are performed with variation of basic process parameters such as powder layer thickness (0-120μm), hatch
distance (60μm-1000μm), and fabrication strategy (the so-called "one-zone" and "two-zone").
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Fast growth of diamond crystals in open air was achieved by laser-assisted combustion synthesis through vibrational
excitation of precursor molecules. A wavelength-tunable CO2 laser (spectrum range from 9.2 to 10.9 μm) was used for
the vibrational excitation in synthesis of diamond crystals. A pre-mixed C2H4/C2H2/O2 gas mixture was used as
precursors. Through resonant excitation of the CH2-wagging mode of ethylene (C2H4) molecules using the CO2 laser
tuned at 10.532 Μm, high-quality diamond crystals were grown on silicon substrates with a high growth rate of ~139
μm/hr. Diamond crystals with a length up to 5 mm and a diameter of 1 mm were grown in 36 hours. Sharp Raman peaks
at 1332 cm-1 with full width at half maximum (FWHM) values around 4.5 cm-1 and distinct X-ray diffraction spectra
demonstrated the high quality of the diamond crystals. The effects of the resonant excitation of precursor molecules by
the CO2 laser were investigated using optical emission spectroscopy.
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Periodic diameter modulation of carbon nanotubes (CNTs) by quick temperature variation was successfully achieved in
laser-assisted chemical vapor deposition process. Tapered and diameter-alternating CNTs were grown by periodic
modulation of the temperature due to inverse relationship between the temperature and the diameter of the CNTs. The
diameter-modulated single-walled carbon nanotubes (SWNTs) were integrated into field-effect transistors (FETs)
structure to investigate their electronic transport properties. The tapered SWNTs showed electronic properties similar to
Schottky diodes indicating clear evidence of different bandgaps at two ends of the tubes. However, the electronic
transport of the diameter-modulated SWNTs showed a very small current magnitude which is attributed to the large
number of defects and the electron confinement in the periodic quantum well arrays. Transmission electron microscopy
and Raman spectroscopy were also studied to investigate the structural and electronic properties of the structures.
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The nonlinear absorption character determines a high potential of ultrafast laser pulses for 3D processing of transparent
materials, particularly for optical functions. This is based on refractive index engineering involving thermo-mechanical,
and structural rearrangements of the dielectric matrix. Challenges are related to the time-effectiveness of irradiation,
correct beam delivery, and the influence of material properties on the exposure results. Particularly for light-guiding
applications it is suitable to master positive refractive index changes in a time-efficient manner, considering that the
result depends on the deposited energy and its relaxation paths. To address these challenges several irradiation concepts
based on adaptive optics in spatial and temporal domains were developed. We review here some of the applications from
various perspectives. A physical aspect is related to temporal pulse shaping and time-synchronized energy delivery tuned
to material transient reactions, enabling thus a synergetic interaction between light and matter and, therefore, optimal
results. Examples will be given concerning refractive index flip in thermally expansive glasses by thermo-mechanical
regulation and energy confinement by nonlinear control. A second engineering aspect is related to processing efficiency.
We give insights into beam-delivery corrections and 3D parallel complex photoinscription techniques utilizing dynamic
wavefront engineering. Additionally, in energetic regimes, ultrafast laser radiation can generate an intriguing nanoscale
spontaneous arrangement, leading to form birefringence and modulated index patterns. Using the birefringence
properties and the deriving anisotropic optical character, polarization sensitive devices were designed and fabricated. The
polarization sensitivity allows particular light propagation and confinement properties in 3D structures.
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Flexible organic photovoltaics have gained increasing interests during the last decades. Toward increasing the
efficiency and decreasing the cost per Watt, they are on their way to the market. The approach of laser patterning
technology has been expected to motivate the industrialization of organic photovoltaics. In this paper high repetition
picosecond laser radiation fabricated trenches of ITO on flexible PET (Polyethylene terephthalate) substrate are
presented. In order to obtain clean removal ITO layer without damaging PET substrate, 1064nm, 532nm and 355nm
wavelengths with different laser fluencies and scanning strategies are applied and optimized. The results reveal the
different principles for ablation of ITO layer with different wavelengths. The ITO layer is successfully and selectively
removed by 1064nm laser radiation with 0.63J/cm2 fluence and 4m/s scanning speed.
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In this contribution, we report on a laser-chemical removal method for precise machining of micro forming tools.
Thereby, a focused machining laser beam is guided coaxially to an etchant jet stream. Since the material removal is
caused by laser-induced chemical reactions using this method, machining is achieved at low laser powers. Hence,
material stressing involving micro cracks and further parasitic effects can be avoided. Due to these advantages, this
method offers a suitable technique for the finishing of precision micro tools. Several experiments have been performed at
rotary swaging jaws made of Stellite 21 in order to chamfer the edged transition section between the operating sphere
and the tool flank. The influence of both different laser powers and work piece traverse speeds has been investigated. For
this purpose, several parallel laser paths were applied along the edged transition section when varying the process
parameters. Here, the incident laser beam is subjected to different angles of incidence. Due to reflection effects, the
process parameters have to be matched with respect to the particular angle of incidence during the machining. In this
vein, the edged transition section of rotary swaging jaws was chamfered at radii in the range of 120 μm.
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Ultrafast laser pulses are a powerful tool to process dielectrics. Here, we review our recent work concerning high aspect
ratio micro and nanochannel processing in glass. We show how femtosecond Bessel beams overcome many of the
difficulties associated with Gaussian beams. We report on single shot processing of nanochannels with aspect ratio up to
100. Underlying physical phenomena are discussed.
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A near infrared sub-15 femtosecond laser scanning microscope was employed for structuring of bulk colored glass and
polymethylmethacrylate (PMMA). The 400-mW Ti-Sapphire laser operates at 85 MHz with an M-shaped emission
spectrum with maxima at 770 nm and 827 nm. Using a high numerical aperture objective light intensity of about
7 TW/cm2 at the focal plane can be reached. For PMMA a mean power of less than 17 mW, which corresponds to a pulse
energy of 0.2 nJ, was sufficient for ablating material. Holes of a diameter of less than 170 nm were produced. Two-photon
fluorescence measurements, which can be performed with the same microscope, reveal an extension of the focus
length in the specimen, which is most likely caused by self-focusing effects. By applying the same power, the refractive
index of the glass could be changed. Islands at the glass surface of a size of less than 100 nm have been produced.
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Recent year, they require the high performances of laser as a light source in variety application area. For instance, those
are a shorter wavelength, a shorter pulse width. In order to serve those needs, an improvement of the laser damage
threshold value of optical element used in the laser applications is required. And they reported that a surface-roughness
of glass substrate as used coated optical element exert also influence that. Currently, the chemical mechanical polishing
method (CMP method) is general used as the polishing method of optical element. This method is a friction method.
Therefore, the reduction of the surface-roughness is prevented by generation of scratches and digs that keep happening
by contamination in slurry. In order to solve this problem, we propose the optical near-field etching method (ONE). The
ONE is operated by irradiation of a SHG light (λ=532nm) of Nd:YAG laser on glass substrate in chlorine gas
atmosphere that have a optical absorption band edge of 400nm. The radical formation of the chlorine molecular is
created by non-adiabatic photochemical reaction due to optical near-field occurred in glass surface. And the etching is
progressed in the projection of glass surface. With this processing, we can achieve the reduction of Ra value of surfaceroughness
from 0.2nm to 0.13nm. In addition, we gave the mirror coating to the glass substrate to which the surfaceroughness
was improved by ONE and measured the laser damage threshold value. Accordingly, we obtained 14.0J/cm2as the laser damage threshold value. The laser damage threshold value of the glass substrate without ONE is 8.2J/cm2. It
is shown that the laser damage threshold increase by 1.7 times by ONE.
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Highly efficient diffractive beam splitters surface-structured on submicron scale are presented. Submicron relief
structures formed on the surfaces of a splitter work as an anti-reflective layer to improve the beam-splitting efficiency.
Surface structuring is conducted using deep-UV, liquid-immersion interference lithography and dry etching. Rigorously
designed structures with a period of 140 nm and a depth of 55 nm are lithographed onto fused-silica splitters. Splitting
efficiencies at 266 nm are increased by 8% to agree favorably with a theoretical value, while Fresnel reflections are
substantially reduced. Surface-structured beam splitters reported here are of great use in industrial machining
applications using high-power pulsed lasers.
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Laser induced forward transfer (LIFT) is used to print Li-ion battery electrodes. We show a preferred orientation of
LiCoO2 particles in the (003) direction relative to non-laser transferred materials. While the laser energy does not alter
the degree of orientation, the number of passes and transfer distance both have a significant influence on the observed
texturing. We use a geometric argument based on the arrangement of plate-like particles on the substrate to explain the
observations. When the plate-like particles encounter a perfectly flat substrate, they are able to align flat, causing (003)
domains parallel to the substrate to be over 30 times more predominant than either (101) and (104) domains. From this
maximum degree of orientation subsequent passes decrease the overall texturing of the samples as transferred particles
encounter increasingly rough surfaces. At larger transfer distances, the areal density of particles reaching the substrate
decreases, resulting in increased available substrate surface area and therefore more predominant particle orienting.
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The material development for advanced lithium-ion batteries plays an important role in future mobile applications and
energy storage systems. It is assumed that electrode materials made of nano-composited materials will improve battery
lifetime and will lead to an enhancement of lithium diffusion and thus improve battery capacity and cyclability. A major
problem concerning thin film electrodes is, that increasing film thickness leads to an increase in lithium diffusion path
lengths and thereby a decrease in power density. To overcome this problem, the investigation of a 3D-battery system
with an increased surface area is necessary. UV-laser micromachining was applied to create defined line or grating
structures via mask imaging. SnO2 is a highly investigated anode material for lithium-ion batteries. Yet, the enormous
volume changes occurring during electrochemical cycling lead to immense loss of capacity. The formation of micropatterns
via laser ablation to create structures which enable the compensation of the volume expansion was investigated
in detail. Thin films of SnO2 were deposited in Ar:O2 atmosphere via r.f. magnetron sputtering on silicon and stainless
steel substrates. The thin films were studied with X-ray diffraction to determine their crystallinity. The electrochemical
properties of the manufactured films were investigated via electrochemical cycling against a lithium anode.
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The development of future battery systems is mainly focused on powerful rechargeable lithium-ion batteries. To satisfy
this demand, current studies are focused on cathodes based on nano-composite materials which lead to an increase in
power density of the LIB primarily due to large electrochemically active surface areas. Electrode materials made of
lithium manganese oxides (Li-Mn-O) are assumed to replace commonly used cathode materials like LiCoO2 due to less
toxicity and lower costs. Thin films in the Li-Mn-O system were synthesized by non-reactive r.f. magnetron sputtering of
a LiMn2O4 target on silicon and stainless steel substrates. In order to enhance power density and cycle stability of the
cathode material, direct laser structuring methods were investigated using a laser system operating at a wavelength of
248 nm. Therefore, high aspect ratio micro-structures were formed on the thin films. Laser annealing processes were
investigated in order to achieve an appropriate crystalline phase for unstructured and structured thin films as well as for
an increase in energy density and control of grain size. Laser annealing was realized via a high power diode laser system.
The effects of post-thermal treatment on the thin films were studied with Raman spectroscopy, X-ray diffraction and
scanning electron microscopy. The formation of electrochemically active and inactive phases was discussed. Surface
chemistry was investigated via X-ray photoelectron spectroscopy. Interaction between UV-laser radiation and the thin
film material was analyzed through ablation experiments. Finally, to investigate the electrochemical properties, the
manufactured thin film cathodes were cycled against a lithium anode. The formation of a solid electrolyte interphase on
the cathode side was discussed.
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Selective thin film structuring with laser beams was already being deployed in industries such as
the display industry and the photovoltaic industry. However developments in tailored
performances of laser beams, such as spatial profile, temporal behaviour and wavelength will
improve the resource efficiency and reduce the production cost and this in turn will make more
applications accessible. For optimizing selective thin film structuring different wavelengths were
used. In this paper the results will be presented and discussed.
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Photovoltaics/Energy Devices: Joint Session with Conference 7920
The ALPINE project is developing innovative fiber lasers for the scribing of new thin film photovoltaic modules with the
aims to push forward the European research and development of fiber laser systems and solar energy exploitation. The
fiber lasers will be based on photonic crystal fibers, which are characterized by unusual and interesting light guiding
properties exploited to deliver high power with excellent beam quality and high resonator stability and efficiency, and
will be applied to substitute mechanical scribing steps in the photovoltaic module production. In addition, new
photovoltaic thin film technologies is applied, which is based on cadmium telluride and copper indium diselenide
materials. With a potential conversion efficiency just below that of crystalline silicon, these new material approaches are
ready to enter the market with low manufacturing costs for immediate economic or environment impact.
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Low-damage laser scribing of thin films to perform series interconnection (external and integrated) of thin-film CIGS
solar cells for module fabrication is still a challenge. In consequence, the influence of laser scribing parameters on the
electrical characteristics of thin-film CIGS solar cells must be studied in addition to standard analytical techniques for
imaging and spectroscopy. Hence, CIGS solar cells were scribed with ultrashort Ti:Sapphire laser pulses with a
wavelength of 775 nm and a pulse length of 150 fs. The I-V curves with the open circuit voltage, parallel, and series
resistance were measured directly after the laser-scribing process and were compared with initial cell parameters. Apart
from studying the influence of laser fluence etc. also various laser-scribing geometries were examined. The most
significant effect of the laser-scribing procedure can be found for the parallel resistance. Laser ablation and laser-induced
material modifications during scribing results in (i) alterations of the material properties of the films, e.g. the CIGS, and
(ii) material modifications outside of the laser scribe, where the interfaces, e.g. p-n junction, primarily are effected; both
effects are leading to the sudden decrease in parallel resistance. Morphology, topography, geometry and material
modifications of the laser-scribed areas were analyzed by scanning electron microscopy (SEM) in combination with
energy-dispersive X-ray spectroscopy (EDX) and focused ion beam (FIB) cross sectioning. The results of the laserscribing
induced alterations are discussed in relation to the applied scribing parameters. A model is introduced to
improve the understanding of the physical reasons of the measured solar cell degradation while scribing.
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Flexible large area organic photovoltaic (OPV) is currently one of the fastest developing areas of organic electronics.
New light absorbing polymer blends combined with new transparent conductive materials provide higher power
conversion efficiencies while new and improved production methods are developed to achieve higher throughput at
reduced cost. A typical OPV is formed by TCO layers as the transparent front contact and polymers as active layer as
well as interface layer between active layer and front contact. The several materials have to be patterned in order to allow
for a row connection of the solar cell. 3D-Micromac used ultra-short pulsed lasers to evaluate the applicability of various
wavelengths for the selective ablation of the indium tin oxide (ITO) layer and the selective ablation of the bulk hetero
junction (BHJ) consisting of poly(3-hexylthiophene):phenyl-C61-butyric acid methyl ester (P3HT:PCBM) on top of a
Poly(3,4-ethylenedioxythiophene) poly(styrenesulfonate) (PEDOT:PSS) without damaging the ITO. These lasers in
combination with high performance galvanometer scanning systems achieve superior scribing quality without damaging
the substrate. With scribing speeds of 10 m/s and up it is possible to integrate this technology into a roll-to-roll
manufacturing tool. The functionality of an OPV usually also requires an annealing step, especially when using a BHJ
for the active layer consisting of P3HT:PCBM, to optimize the layers structure and therewith the efficiency of the solar
cell (typically by thermal treatment, e.g. oven). The process of laser annealing was investigated using a short-pulsed laser
with a wavelength close to the absorption maximum of the BHJ.
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We report on fast and flexible laser processing technology for crystalline solar cells by using ultra-short laser pulses and
a combination of Diffractive Optical Elements (DOE´s) for beam splitting with conventional scanner technology. The
focus is laid on damage reduction, decreasing processing times, and efficient processing strategies. We demonstrate the
process conversion from single-spot to multi-spot ablation of thin-films and bulk material, e.g. nitride ablation and edge
isolation. We will point out an increase in ablation efficiency by a factor of 3 and an additional increase in processing
speed by a factor of > 50 for surface ablation processes. The DOE in combination with scanner technology provides a
fast and flexible system where only an industrial proven DOE has to be implemented in front of the scanner. Due to this
modification the technology can be easily adapted. Using multi-spot technology for processing of crystalline solar cells,
heat accumulation has to be analyzed. Limitations in spot distance and geometrical arrangements are discussed and
described mathematically. Results and process windows will be shown for a thin-film ablation (surface) and a laser edge
isolation (bulk) process on crystalline solar cells. An estimation of cycle times and area throughput will show the
potential for using DOE´s especially combined with ultra-short pulse lasers.
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