Patent application number | Description | Published |
20090042320 | METHODS FOR LIQUID TRANSFER COATING OF THREE-DIMENSIONAL SUBSTRATES - Methods here disclosed provide for selectively coating the top surfaces or ridges of a 3-D substrate while avoiding liquid coating material wicking into micro cavities on 3-D substrates. The substrate includes holes formed in a three-dimensional substrate by forming a sacrificial layer on a template. The template includes a template substrate with posts and trenches between the posts. The steps include subsequently depositing a semiconductor layer and selectively etching the sacrificial layer. Then, the steps include releasing the semiconductor layer from the template and coating the 3-D substrate using a liquid transfer coating step for applying a liquid coating material to a surface of the 3-D substrate. The method may further include coating the 3-D substrate by selectively coating the top ridges or surfaces of the substrate. Additional features may include filling the micro cavities of the substrate with a filling material, removing the filling material to expose only the substrate surfaces to be coated, coating the substrate with a layer of liquid coating material, and removing said filling material from the micro cavities of the substrate. | 02-12-2009 |
20100116316 | TRUNCATED PYRAMID STRUCTURES FOR SEE-THROUGH SOLAR CELLS - The present disclosure presents a partially-transparent (see-through) three-dimensional thin film solar cell (3-D TFSC) substrate. The substrate includes a plurality of unit cells. Each unit cell structure has the shape of a truncated pyramid, and its parameters may be varied to allow a desired portion of sunlight to pass through. | 05-13-2010 |
20100148318 | Three-Dimensional Semiconductor Template for Making High Efficiency Thin-Film Solar Cells - A semiconductor template having a top surface aligned along a (100) crystallographic orientation plane and an inverted pyramidal cavity defined by a plurality of walls aligned along a (111) crystallographic orientation plane. A method for manufacturing a semiconductor template by selectively removing silicon material from a silicon template to form a top surface aligned along a (100) crystallographic plane of the silicon template and a plurality of walls defining an inverted pyramidal cavity each aligned along a (111) crystallographic plane of the silicon template. | 06-17-2010 |
20100148319 | Substrates for High-Efficiency Thin-Film Solar Cells Based on Crystalline Templates - A three-dimensional thin-film semiconductor substrate having a plurality of ridges on the surface of the semiconductor substrate which define a base opening of an inverted pyramidal cavity and walls defining the inverted pyramidal cavity is provided. And a fabrication method for a 3-D TFSS by forming a porous silicon layer on a silicon template having a top surface aligned along a (100) crystallographic orientation plane of the silicon template and a plurality of walls each aligned along a (111) crystallographic orientation plane of the silicon template and forming an inverted pyramidal cavity. The porous silicon layer forms substantially conformal on the silicon template. Then forming a substantially conformal epitaxial silicon layer on the porous silicon layer and releasing the epitaxial silicon layer from the silicon template. | 06-17-2010 |
20100175752 | High-Efficiency Thin-Film Solar Cells - A three-dimensional solar cell comprising a semiconductor substrate with an inverted pyramidal cavity, emitter metallization regions on ridges on the surface of the semiconductor substrate which define an opening of the inverted pyramidal cavity, and base metallization regions on a region which form the apex of the inverted pyramidal cavity. A method for fabricating a three-dimensional thin-film solar cell from an inverted pyramidal three-dimensional thin-film silicon substrate by doping ridges on the surface of the semiconductor substrate which define an opening of an inverted pyramidal cavity on the substrate to form an emitter region, and doping a region which forms the apex of the inverted pyramidal cavity to form a base region. Adding a surface passivation layer to the surface of the substrate. Selectively etching the passivation layer from the emitter region and base region. Then concurrently metallizing the emitter region and base region. | 07-15-2010 |
20100203711 | Trench Formation Method For Releasing A Thin-Film Substrate From A Reusable Semiconductor Template - A method is provided for fabricating a thin-film semiconductor substrate by forming a porous semiconductor layer conformally on a reusable semiconductor template and then forming a thin-film semiconductor substrate conformally on the porous semiconductor layer. An inner trench having a depth less than the thickness of the thin-film semiconductor substrate is formed on the thin-film semiconductor substrate. An outer trench providing access to the porous semiconductor layer is formed on the thin-film semiconductor substrate and is positioned between the inner trench and the edge of the thin-film semiconductor substrate. The thin-film semiconductor substrate is then released from the reusable semiconductor template. | 08-12-2010 |
20100267186 | METHOD FOR FABRICATING A THREE-DIMENSIONAL THIN-FILM SEMICONDUCTOR SUBSTRATE FROM A TEMPLATE - A method is presented for fabrication of a three-dimensional thin-film solar cell semiconductor substrate from a template. A semiconductor template having three-dimensional surface features comprising a top surfaces substantially aligned along a ( | 10-21-2010 |
20100279494 | Method For Releasing a Thin-Film Substrate - The present disclosure relates to methods for selectively etching a porous semiconductor layer to separate a thin-film semiconductor substrate (TFSS) having planar or three-dimensional features from a corresponding semiconductor template. The method involves forming a conformal sacrificial porous semiconductor layer on a template. Next, a conformal thin film silicon substrate is formed on top of the porous silicon layer. The middle porous silicon layer is then selectively etched to separate the TFSS and semiconductor template. The disclosed advanced etching chemistries and etching methods achieve selective etching with minimal damage to the TFSS and template. | 11-04-2010 |
20100294333 | STRUCTURE AND METHOD FOR IMPROVING SOLAR CELL EFFICIENCY AND MECHANICAL STRENGTH - The present disclosure presents a three-dimensional thin film solar cell (3-D TFSC) substrate having enhanced mechanical strength, light trapping, and metal modulation coverage properties. The substrate includes a plurality of unit cells, which may or may not be different. Unit cells are defined as a small self-contained geometrical pattern which may be repeated. Each unit cell structure includes a wall enclosing a trench. Further, the unit cell includes an aperture having an aperture diameter. For the purposes of the present disclosure, the dimensions of interest include wall thickness, wall height, and aperture diameter. A pre-determined variation in these dimensions among unit cells across the substrate produces specific advantages. | 11-25-2010 |
20100300518 | THREE-DIMENSIONAL THIN-FILM SEMICONDUCTOR SUBSTRATE WITH THROUGH-HOLES AND METHODS OF MANUFACTURING - A method for the fabrication of a three-dimensional thin-film semiconductor substrate with selective through-holes is provided. A porous semiconductor layer is conformally formed on a semiconductor template comprising a plurality of three-dimensional inverted pyramidal surface features defined by top surface areas aligned along a (100) crystallographic orientation plane of the semiconductor template and a plurality of inverted pyramidal cavities defined by sidewalls aligned along the (111) crystallographic orientation plane of the semiconductor template. An epitaxial semiconductor layer is conformally formed on the porous semiconductor layer. The epitaxial semiconductor layer is released from the semiconductor template. Through-holes are selectively formed in the epitaxial semiconductor layer with openings between the front and back lateral surface planes of the epitaxial semiconductor layer to form a partially transparent three-dimensional thin-film semiconductor substrate. | 12-02-2010 |
20110021006 | METHOD FOR RELEASING A THIN SEMICONDUCTOR SUBSTRATE FROM A REUSABLE TEMPLATE - The present disclosure relates to methods and apparatuses for releasing a thin semiconductor substrate from a reusable template. The method involves forming a mechanically weak layer conformally on a semiconductor template. Then forming a thin semiconductor substrate conformally on the mechanically weak layer. The thin semiconductor substrate, the mechanically weak layer and the template forming a wafer. Then defining the border of the thin-film semiconductor substrate to be released by exposing the peripheral of the mechanically weak layer. Then releasing the thin-film semiconductor substrate by applying a controlled air flow parallel to said mechanically weak layer wherein the controlled air flow separates the thin semiconductor substrate and template according to lifting forces. | 01-27-2011 |
20110256654 | DOUBLE-SIDED REUSABLE TEMPLATE FOR FABRICATION OF SEMICONDUCTOR SUBSTRATES FOR PHOTOVOLTAIC CELL AND MICROELECTRONICS DEVICE MANUFACTURING - This disclosure presents manufacturing methods and apparatus designs for making TFSSs from both sides of a re-usable semiconductor template, thus effectively increasing the substrate manufacturing throughput and reducing the substrate manufacturing cost. This approach also reduces the amortized starting template cost per manufactured substrate (TFSS) by about a factor of 2 for a given number of template reuse cycles. | 10-20-2011 |
20120021560 | TRUNCATED PYRAMID STRUCTURES FOR SEE-THROUGH SOLAR CELLS - The present disclosure presents a partially-transparent (see-through) three-dimensional thin film solar cell (3-D TFSC) substrate. The substrate includes a plurality of unit cells. Each unit cell structure has the shape of a truncated pyramid, and its parameters may be varied to allow a desired portion of sunlight to pass through. | 01-26-2012 |
20120103408 | BACKPLANE REINFORCEMENT AND INTERCONNECTS FOR SOLAR CELLS - Fabrication methods and structures relating to backplanes for back contact solar cells that provide for solar cell substrate reinforcement and electrical interconnects are described. The method comprises depositing an interdigitated pattern of base electrodes and emitter electrodes on a backside surface of a semiconductor substrate, forming electrically conductive emitter plugs and base plugs on the interdigitated pattern, and attaching a backplane having a second interdigitated pattern of base electrodes and emitter electrodes at the conductive emitter and base plugs to form electrical interconnects. | 05-03-2012 |
20120125256 | APPARATUS AND METHOD FOR REPEATEDLY FABRICATING THIN FILM SEMICONDUCTOR SUBSTRATES USING A TEMPLATE - Mechanisms are disclosed by which a semiconductor wafer, silicon in some embodiments, is repeatedly used to serve as a template and carrier for fabricating high efficiency capable thin semiconductor solar cells substrates. Mechanisms that enable such repeated use of these templates at consistent quality and with high yield are disclosed. | 05-24-2012 |
20120167819 | METHOD FOR RECONSTRUCTING A SEMICONDUCTOR TEMPLATE - The disclosed subject matter pertains to deposition of thin film or thin foil materials in general, but more specifically to deposition of epitaxial monocrystalline or quasi-monocrystalline silicon film (epi film) for use in manufacturing of high efficiency solar cells. In operation, methods are disclosed which extend the reusable life and to reduce the amortized cost of a substrate or template used in the manufacturing process of silicon solar cells. Further, methods are disclosed which provide for the conversion of a low quality starting surface into an improved quality starting surface of a silicon wafer. | 07-05-2012 |
20120174861 | THREE-DIMENSIONAL SEMICONDUCTOR TEMPLATE FOR MAKING HIGH EFFICIENCY THIN-FILM SOLAR CELLS - A semiconductor template having a top surface aligned along a (100) crystallographic orientation plane and an inverted pyramidal cavity defined by a plurality of walls aligned along a (111) crystallographic orientation plane. A method for manufacturing a semiconductor template by selectively removing silicon material from a silicon template to form a top surface aligned along a (100) crystallographic plane of the silicon template and a plurality of walls defining an inverted pyramidal cavity each aligned along a (111) crystallographic plane of the silicon template. | 07-12-2012 |
20120272490 | METHOD FOR RELEASING A THIN SEMICONDUCTOR SUBSTRATE FROM A REUSABLE TEMPLATE - The present disclosure relates to methods and apparatuses for releasing a thin semiconductor substrate from a reusable template. The method involves forming a mechanically weak layer conformally on a semiconductor template. Then forming a thin semiconductor substrate conformally on the mechanically weak layer. The thin semiconductor substrate, the mechanically weak layer and the template forming a wafer. Then defining the border of the thin-film semiconductor substrate to be released by exposing the peripheral of the mechanically weak layer. Then releasing the thin-film semiconductor substrate by applying a controlled air flow parallel to said mechanically weak layer wherein the controlled air flow separates the thin semiconductor substrate and template according to lifting forces. | 11-01-2012 |
20120305063 | HIGH-EFFICIENCY PHOTOVOLTAIC BACK-CONTACT SOLAR CELL STRUCTURES AND MANUFACTURING METHODS USING THIN PLANAR SEMICONDUCTOR ABSORBERS - Back contact back junction solar cell and methods for manufacturing are provided. The back contact back junction solar cell comprises a substrate having a light capturing frontside surface with a passivation layer, a doped base region, and a doped backside emitter region with a polarity opposite the doped base region. A backside passivation layer and patterned reflective layer on the emitter form a light trapping backside mirror. An interdigitated metallization pattern is positioned on the backside of the solar cell and a permanent reinforcement provides support to the cell. | 12-06-2012 |
20130000715 | ACTIVE BACKPLANE FOR THIN SILICON SOLAR CELLS - Fabrication methods and structures relating to backplanes for back contact solar cells that provide for solar cell substrate reinforcement and electrical interconnects are described. The method comprises depositing an interdigitated pattern of base electrodes and emitter electrodes on a backside surface of a semiconductor substrate, attaching a prepeg backplane to the interdigitated pattern of base electrodes and emitter electrodes, forming holes in the prepeg backplane which provide access to the first layer of electrically conductive metal, and depositing a second layer of electrically conductive metal on the backside surface of the prepeg backplane forming an electrical interconnect with the first layer of electrically conductive metal through the holes in the prepeg backplane. | 01-03-2013 |
20130140838 | MOBILE VACUUM CARRIERS FOR THIN WAFER PROCESSING - This disclosure presents mobile vacuum carriers that may be used to support thin substrates that would otherwise be too brittle to transport and process. This disclosure relates to the processing of thin semiconductor substrates and has particular applicability to the fields of photovoltaic solar cells, semiconductor microelectronic integrated circuits, micro-electro-mechanical systems (MEMS), optoelectronic devices (such as light-emitting diodes, lasers, photo detectors), data storage devices, etc. | 06-06-2013 |
20130141833 | MOBILE ELECTROSTATIC CARRIERS FOR THIN WAFER PROCESSING - In one embodiment, there is provided a carrier comprising a top semiconductor layer having isolated positive electrode regions and isolated negative electrode regions separated by a frontside trench through the top semiconductor layer at least to an underlying insulating layer positioned between the top semiconductor layer and a bottom semiconductor layer. A dielectric layer covers the top exposed surfaces of the carrier. Backside trenches through the bottom semiconductor layer at least to the insulating layer form isolated backside regions corresponding to the frontside positive and negative electrode regions. Backside contacts positioned on the bottom semiconductor layer and coupled to the positive and negative electrode regions allow for the electric charging of the frontside electrode regions. | 06-06-2013 |
20130167915 | HIGH-EFFICIENCY PHOTOVOLTAIC BACK-CONTACT SOLAR CELL STRUCTURES AND MANUFACTURING METHODS USING THREE-DIMENSIONAL SEMICONDUCTOR ABSORBERS - Back contact back junction three dimensional solar cell and methods for manufacturing are provided. The back contact back contact back junction three dimensional solar cell comprises a three-dimensional substrate. The substrate comprises a light capturing frontside surface with a passivation layer, a doped base region, and a doped backside emitter region with a polarity opposite the doped base region. A backside passivation layer is positioned on the doped backside emitter region. Backside emitter contacts and backside base contacts connected to metal interconnects and selectively formed on three-dimensional features of the backside of three-dimensional solar cell. | 07-04-2013 |
20130171808 | DOUBLE-SIDED REUSABLE TEMPLATE FOR FABRICATION OF SEMICONDUCTOR SUBSTRATES FOR PHOTOVOLTAIC CELL AND MICROELECTRONICS DEVICE MANUFACTURING - This disclosure presents manufacturing methods and apparatus designs for making TFSSs from both sides of a re-usable semiconductor template, thus effectively increasing the substrate manufacturing throughput and reducing the substrate manufacturing cost. This approach also reduces the amortized starting template cost per manufactured substrate (TFSS) by about a factor of 2 for a given number of template reuse cycles. | 07-04-2013 |
20130233378 | HIGH-EFFICIENCY PHOTOVOLTAIC BACK-CONTACT SOLAR CELL STRUCTURES AND MANUFACTURING METHODS USING SEMICONDUCTOR WAFERS - A back contact back junction solar cell using semiconductor wafers and methods for manufacturing are provided. The back contact back junction solar cell comprises a semiconductor wafer having a doped base region, a light capturing frontside surface, and a doped backside emitter region. A frontside and backside dielectric layer and passivation layer provide enhance light trapping and internal reflection. Backside base and emitter contacts are connected to metal interconnects forming a metallization pattern of interdigitated fingers and busbars on the backside of the solar cell. | 09-12-2013 |
20130273721 | Trench Formation Method For Releasing A Thin-Film Substrate From A Reusable Semiconductor Template - A method is provided for fabricating a thin-film semiconductor substrate by forming a porous semiconductor layer conformally on a reusable semiconductor template and then forming a thin-film semiconductor substrate conformally on the porous semiconductor layer. An inner trench having a depth less than the thickness of the thin-film semiconductor substrate is formed on the thin-film semiconductor substrate. An outer trench providing access to the porous semiconductor layer is formed on the thin-film semiconductor substrate and is positioned between the inner trench and the edge of the thin-film semiconductor substrate. The thin-film semiconductor substrate is then released from the reusable semiconductor template. | 10-17-2013 |
20130280887 | Method For Releasing a Thin-Film Substrate - The present disclosure relates to methods for selectively etching a porous semiconductor layer to separate a thin-film semiconductor substrate (TFSS) having planar or three-dimensional features from a corresponding semiconductor template. The method involves forming a conformal sacrificial porous semiconductor layer on a template. Next, a conformal thin film silicon substrate is formed on top of the porous silicon layer. The middle porous silicon layer is then selectively etched to separate the TFSS and semiconductor template. The disclosed advanced etching chemistries and etching methods achieve selective etching with minimal damage to the TFSS and template. | 10-24-2013 |
20130284255 | High-Efficiency Thin-Film Solar Cells - A three-dimensional solar cell comprising a semiconductor substrate with an inverted pyramidal cavity, emitter metallization regions on ridges on the surface of the semiconductor substrate which define an opening of the inverted pyramidal cavity, and base metallization regions on a region which form the apex of the inverted pyramidal cavity. A method for fabricating a three-dimensional thin-film solar cell from an inverted pyramidal three-dimensional thin-film silicon substrate by doping ridges on the surface of the semiconductor substrate which define an opening of an inverted pyramidal cavity on the substrate to form an emitter region, and doping a region which forms the apex of the inverted pyramidal cavity to form a base region. Adding a surface passivation layer to the surface of the substrate. Selectively etching the passivation layer from the emitter region and base region. Then concurrently metallizing the emitter region and base region. | 10-31-2013 |
20130288418 | METHOD FOR FABRICATING A THREE-DIMENSIONAL THIN-FILM SEMICONDUCTOR SUBSTRATE FROM A TEMPLATE - A method is presented for fabrication of a three-dimensional thin-film solar cell semiconductor substrate from a template. A semiconductor template having three-dimensional surface features comprising a top surfaces substantially aligned along a (100) crystallographic plane of semiconductor template and a plurality of inverted pyramidal cavities defined by sidewalls substantially aligned along a (111) crystallographic plane is formed according to an anisotropic etching process. A dose of relatively of high energy light-mass species is implanted in the template at a uniform depth and parallel to the top surfaces and said sidewalls defining the inverted pyramidal cavities of the template. The semiconductor template is annealed to convert the dose of relatively of high energy light-mass species to a mechanically-weak-thin layer. The semiconductor template is cleaved along the mechanically-weak-thin layer to release a three-dimensional thin-film semiconductor substrate from the semiconductor template. | 10-31-2013 |
20130319520 | THREE-DIMENSIONAL THIN-FILM SEMICONDUCTOR SUBSTRATE WITH THROUGH-HOLES AND METHODS OF MANUFACTURING - A three-dimensional thin-film semiconductor substrate with selective through-holes is provided. The substrate having an inverted pyramidal structure comprising selectively formed through-holes positioned between the front and back lateral surface planes of the semiconductor substrate to form a partially transparent three-dimensional thin-film semiconductor substrate. | 12-05-2013 |
20140127834 | METHODS FOR LIQUID TRANSER COATING OF THREE-DIMENSIONAL SUBSTRATES - Methods here disclosed provide for selectively coating the top surfaces or ridges of a 3-D substrate while avoiding liquid coating material wicking into micro cavities on 3-D substrates. The substrate includes holes formed in a three-dimensional substrate by forming a sacrificial layer on a template. The template includes a template substrate with posts and trenches between the posts. The steps include subsequently depositing a semiconductor layer and selectively etching the sacrificial layer. Then, the steps include releasing the semiconductor layer from the template and coating the 3-D substrate using a liquid transfer coating step for applying a liquid coating material to a surface of the 3-D substrate. The method may further include coating the 3-D substrate by selectively coating the top ridges or surfaces of the substrate. | 05-08-2014 |
20150020877 | HIGH-EFFICIENCY SOLAR PHOTOVOLTAIC CELLS AND MODULES USING THIN CRYSTALLINE SEMICONDUCTOR ABSORBERS - Fabrication methods and structures relating to backplanes for back contact solar cells that provide for solar cell substrate reinforcement and electrical interconnects as well as Fabrication methods and structures for forming thin film back contact solar cells are described. | 01-22-2015 |
20150061086 | THREE-DIMENSIONAL SEMICONDUCTOR TEMPLATE FOR MAKING HIGH EFFICIENCY THIN-FILM SOLAR CELLS - A semiconductor template having a top surface aligned along a (100) crystallographic orientation plane and an inverted pyramidal cavity defined by a plurality of walls aligned along a (111) crystallographic orientation plane. A method for manufacturing a semiconductor template by selectively removing silicon material from a silicon template to form a top surface aligned along a (100) crystallographic plane of the silicon template and a plurality of walls defining an inverted pyramidal cavity each aligned along a (111) crystallographic plane of the silicon template. | 03-05-2015 |