Patent application number | Description | Published |
20120192913 | MIXED TEMPERATURE DEPOSITION OF THIN FILM SILICON TANDEM CELLS - Fabrication of a tandem photovoltaic device includes forming a bottom cell having an N-type layer, a P-type layer and a bottom intrinsic layer therebetween. A top cell is formed relative to the bottom cell. The top cell has an N-type layer, a P-type layer and a top intrinsic layer therebetween. The top intrinsic layer is formed of an undoped material deposited at a temperature that is different from the bottom intrinsic layer such that band gap energies for the top intrinsic layer and the bottom intrinsic layer are progressively lower for each cell. | 08-02-2012 |
20120216862 | Silicon: Hydrogen Photovoltaic Devices, Such As Solar Cells, Having Reduced Light Induced Degradation And Method Of Making Such Devices - A method of producing a photovoltaic device includes providing a stretchable substrate for the photovoltaic device; and stretching the substrate to produce a stretched substrate. The method further includes depositing a structure comprising hydrogenated amorphous silicon onto the stretched substrate; and subjecting the deposited hydrogenated amorphous silicon structure and the stretched substrate to a compressive force to form a compressively strained photovoltaic device. | 08-30-2012 |
20120318335 | TANDEM SOLAR CELL WITH IMPROVED TUNNEL JUNCTION - A photovoltaic device and method for fabricating a photovoltaic device include forming a light-absorbing semiconductor structure on a transmissive substrate including a first doped layer and forming an intrinsic layer on the first doped layer, wherein the intrinsic layer includes an amorphous material. The intrinsic layer is treated with a plasma to form seed sites. A first tunnel junction layer is formed on the intrinsic layer by growing microcrystals from the seed sites. | 12-20-2012 |
20120318342 | UNIFORMLY DISTRIBUTED SELF-ASSEMBLED CONE-SHAPED PILLARS FOR HIGH EFFICIENCY SOLAR CELLS - A method for fabricating a photovoltaic device includes applying a diblock copolymer layer on a substrate and removing a first polymer material from the diblock copolymer layer to form a plurality of distributed pores. A pattern forming layer is deposited on a remaining surface of the diblock copolymer layer and in the pores in contact with the substrate. The diblock copolymer layer is lifted off and portions of the pattern forming layer are left in contact with the substrate. The substrate is etched using the pattern forming layer to protect portions of the substrate to form pillars in the substrate such that the pillars provide a radiation absorbing structure in the photovoltaic device. | 12-20-2012 |
20120325305 | OHMIC CONTACT BETWEEN THIN FILM SOLAR CELL AND CARBON-BASED TRANSPARENT ELECTRODE - A photovoltaic device and method include a photovoltaic stack having an N-doped layer, a P-doped layer and an intrinsic layer. A transparent electrode is formed on the photovoltaic stack and includes a carbon based layer and a high work function metal layer. The high work function metal layer is disposed at an interface between the carbon based layer and the P-doped layer such that the high work function metal layer forms a reduced barrier contact and is light transmissive. | 12-27-2012 |
20130000704 | THREE-DIMENSIONAL CONDUCTIVE ELECTRODE FOR SOLAR CELL - A photovoltaic device and method include forming a plurality of pillar structures in a substrate, forming a first electrode layer on the pillar structures and forming a continuous photovoltaic stack including an N-type layer, a P-type layer and an intrinsic layer on the first electrode. A second electrode layer is deposited over the photovoltaic stack such that gaps or fissures occur in the second electrode layer between the pillar structures. The second electrode layer is wet etched to open up the gaps or fissures and reduce the second electrode layer to form a three-dimensional electrode of substantially uniform thickness over the photovoltaic stack. | 01-03-2013 |
20130000706 | TANDEM SOLAR CELL WITH IMPROVED TUNNEL JUNCTION - A photovoltaic device and method for fabricating a photovoltaic device include forming a light-absorbing semiconductor structure on a transmissive substrate including a first doped layer and forming an intrinsic layer on the first doped layer, wherein the intrinsic layer includes an amorphous material. The intrinsic layer is treated with a plasma to form seed sites. A first tunnel junction layer is formed on the intrinsic layer by growing microcrystals from the seed sites. | 01-03-2013 |
20130001657 | SELF-ALIGNED III-V MOSFET DIFFUSION REGIONS AND SILICIDE-LIKE ALLOY CONTACT - A metal oxide semiconductor field effect transistor and method for forming the same include exposing portions on a substrate adjacent to a gate stack, forming a dopant layer over the gate stack and in contact with the substrate in the portions exposed and annealing the dopant layer to drive dopants into the substrate to form self-aligned dopant regions in the substrate. The dopant layer is removed. A metal containing layer is deposited over the gate stack and in contact with the substrate in the exposed portions. The metal containing layer is annealed to drive metal into the substrate to form self-aligned contact regions in a metal alloy formed in the substrate within the dopant regions. The metal layer is then removed. | 01-03-2013 |
20130001659 | SELF-ALIGNED III-V MOSFET DIFFUSION REGIONS AND SILICIDE-LIKE ALLOY CONTACT - A metal oxide semiconductor field effect transistor and method for forming the same include exposing portions on a substrate adjacent to a gate stack, forming a dopant layer over the gate stack and in contact with the substrate in the portions exposed and annealing the dopant layer to drive dopants into the substrate to form self-aligned dopant regions in the substrate. The dopant layer is removed. A metal containing layer is deposited over the gate stack and in contact with the substrate in the exposed portions. The metal containing layer is annealed to drive metal into the substrate to form self-aligned contact regions in a metal alloy formed in the substrate within the dopant regions. The metal layer is then removed. | 01-03-2013 |
20130019929 | REDUCTION OF LIGHT INDUCED DEGRADATION BY MINIMIZING BAND OFFSET - A device and method for reducing degradation in a photovoltaic device includes adjusting a band offset of the device during one or more of forming an electrode, forming a first doped layer or forming an intrinsic layer. The adjusting reduces a band offset between one or more of the electrode, the first doped layer and the intrinsic layer to reduce light-induced degradation of the device. A second doped layer is formed on the intrinsic layer. | 01-24-2013 |
20130049150 | FORMATION OF METAL NANOSPHERES AND MICROSPHERES - Hemispheres and spheres are formed and employed for a plurality of applications. Hemispheres are employed to form a substrate having an upper surface and a lower surface. The upper surface includes peaks of pillars which have a base attached to the lower surface. The peaks have a density defined at the upper surface by an array of hemispherical metal structures that act as a mask during an etch to remove substrate material down to the lower surface during formation of the pillars. The pillars are dense and uniform and include a microscale average diameter. The spheres are formed as independent metal spheres or nanoparticles for other applications. | 02-28-2013 |
20130092213 | EFFICIENCY RESTORATION IN A PHOTOVOLTAIC CELL - The electrical output efficiency of a photovoltaic thermal system can be restored from degradation due to light exposure by annealing a photovoltaic thermal cell at an elevated temperature. The elevated temperature at the photovoltaic thermal cell can be provided by redirecting the flow of a heat exchange fluid to bypass a heat exchanger unit. A boiler unit may be employed to provide additional heating of the heat exchange fluid during the anneal. Further, a variable configuration lid can be provided over a front surface of the photovoltaic thermal cell to control ventilation over the front surface. During the anneal, the position of the variable configuration lid can be set so as to trap heat above the front surface and to elevate the anneal temperature further. | 04-18-2013 |
20130092214 | EFFICIENCY RESTORATION IN A PHOTOVOLTAIC CELL - The electrical output efficiency of a photovoltaic thermal system can be restored from degradation due to light exposure by annealing a photovoltaic thermal cell at an elevated temperature. The elevated temperature at the photovoltaic thermal cell can be provided by redirecting the flow of a heat exchange fluid to bypass a heat exchanger unit. A boiler unit may be employed to provide additional heating of the heat exchange fluid during the anneal. Further, a variable configuration lid can be provided over a front surface of the photovoltaic thermal cell to control ventilation over the front surface. During the anneal, the position of the variable configuration lid can be set so as to trap heat above the front surface and to elevate the anneal temperature further. | 04-18-2013 |
20130095599 | PHOTOVOLTAIC DEVICE USING NANO-SPHERES FOR TEXTURED ELECTRODES - An electronic device includes a substrate and a plurality of particles anchored to the substrate. An electrode material is formed over the particles and configured to form peaks over the particles. One or more operational layers are fog led over the electrode material for performing a device function. | 04-18-2013 |
20130118565 | TEMPERATURE GRADING FOR BAND GAP ENGINEERING OF PHOTOVOLTAIC DEVICES - A method for fabricating a photovoltaic device includes depositing a p-type layer at a first temperature and depositing an intrinsic layer while gradually increasing a deposition temperature to a final temperature. The intrinsic layer deposition is completed at the final temperature. An n-type layer is formed on the intrinsic layer. | 05-16-2013 |
20130221373 | SOLAR CELL MADE USING A BARRIER LAYER BETWEEN P-TYPE AND INTRINSIC LAYERS - A method for forming a photovoltaic device includes depositing a p-type layer on a substrate. A barrier layer is formed on the p-type layer by exposing the p-type layer to an oxidizing agent. An intrinsic layer is formed on the barrier layer, and an n-type layer is formed on the intrinsic layer. | 08-29-2013 |
20130221464 | REDUCED LIGHT DEGRADATION DUE TO LOW POWER DEPOSITION OF BUFFER LAYER - Methods for forming a photovoltaic device include forming a buffer layer between a transparent electrode and a p-type layer. The buffer layer includes a work function that falls substantially in a middle of a barrier formed between the transparent electrode and the p-type layer to provide a greater resistance to light induced degradation. An intrinsic layer and an n-type layer are formed over the p-type layer. | 08-29-2013 |
20130224899 | ENHANCING EFFICIENCY IN SOLAR CELLS BY ADJUSTING DEPOSITION POWER - Methods for forming a photovoltaic device include adjusting a deposition power for depositing a buffer layer including germanium on a transparent electrode. The deposition power is configured to improve device efficiency. A p-type layer is formed on the buffer layer. An intrinsic layer and an n-type layer are formed over the p-type layer. | 08-29-2013 |
20130224900 | SOLAR CELL MADE IN A SINGLE PROCESSING CHAMBER - Methods for forming a photovoltaic device include depositing a p-type layer on a substrate and cleaning the p-type layer by exposing a surface of the p-type layer to a plasma treatment to react with contaminants. An intrinsic layer is formed on the p-type layer, and an n-type layer is formed on the intrinsic layer. | 08-29-2013 |
20130298971 | COST-EFFICENT HIGH POWER PECVD DEPOSITION FOR SOLAR CELLS - A method for forming a photovoltaic device includes providing a substrate. A layer is deposited to form one or more layers of a photovoltaic stack on the substrate. The depositing of the amorphous layer includes performing a high power flash deposition for depositing a first portion of the layer. A low power deposition is performed for depositing a second portion of the layer. | 11-14-2013 |
20130298980 | CONE-SHAPED HOLES FOR HIGH EFFICIENCY THIN FILM SOLAR CELLS - A photovoltaic device includes a substrate having a plurality of hole shapes formed therein. The plurality of hole shapes each have a hole opening extending from a first surface and narrowing with depth into the substrate. The plurality of hole shapes form a hole pattern on the first surface, and the hole pattern includes flat areas separating the hole shapes on the first surface. A photovoltaic device stack is formed on the first surface and extends into the hole shapes. Methods are also provided. | 11-14-2013 |
20130316538 | SURFACE MORPHOLOGY GENERATION AND TRANSFER BY SPALLING - The generation of surface patterns or the replication of surface patterns is achieved in the present disclosure without the need to employ an etching process. Instead, a unique fracture mode referred to as spalling is used in the present disclosure to generate or replicate surface patterns. In the case of surface pattern generation, a surface pattern is provided in a stressor layer and then spalling is performed. In the case of surface pattern replication, a surface pattern is formed within or on a surface of a base substrate, and then a stressor layer is applied. After applying the stressor layer, spalling is performed. Generation or replication of surface patterns utilizing spalling provides a low cost means for generation or replication of surface patterns. | 11-28-2013 |
20140000692 | TRANSPARENT CONDUCTIVE ELECTRODE FOR THREE DIMENSIONAL PHOTOVOLTAIC DEVICE | 01-02-2014 |
20140004648 | TRANSPARENT CONDUCTIVE ELECTRODE FOR THREE DIMENSIONAL PHOTOVOLTAIC DEVICE | 01-02-2014 |
20140004651 | HIGH EFFICIENCY SOLAR CELLS FABRICATED BY INEXPENSIVE PECVD | 01-02-2014 |
20140014162 | EFFICIENCY RESTORATION IN A PHOTOVOLTAIC CELL - The electrical output efficiency of a photovoltaic thermal system can be restored from degradation due to light exposure by annealing a photovoltaic thermal cell at an elevated temperature. The elevated temperature at the photovoltaic thermal cell can be provided by redirecting the flow of a heat exchange fluid to bypass a heat exchanger unit. A boiler unit may be employed to provide additional heating of the heat exchange fluid during the anneal. Further, a variable configuration lid can be provided over a front surface of the photovoltaic thermal cell to control ventilation over the front surface. During the anneal, the position of the variable configuration lid can be set so as to trap heat above the front surface and to elevate the anneal temperature further. | 01-16-2014 |
20140060628 | UNIFORMLY DISTRIBUTED SELF-ASSEMBLED SOLDER DOT FORMATION FOR HIGH EFFICIENCY SOLAR CELLS - A substrate for photovoltaic device includes a textured surface formed from silicon-based material. The textured surface includes a plurality of cones uniformly distributed across the textured surface. The uniformly distributed cones are configured by etching from a top surface of the substrate using a self-assembled solder dot mask evaporated on the substrate prior to etching. The cones are uniformly distributed as a result of gettering a process chamber prior to forming the solder dot mask. The cones have a height/width ratio between about 1 to about 4, and the cones have a density between 10 | 03-06-2014 |
20140065752 | UNIFORMLY DISTRIBUTED SELF-ASSEMBLED SOLDER DOT FORMATION FOR HIGH EFFICIENCY SOLAR CELLS - A method for fabricating a photovoltaic device includes performing a gettering process in a processing chamber which restricts formation of a layer of gettering materials on a substrate and forming a solder layer on the substrate. The solder layer is annealed to form uniformly distributed solder dots which grow on the substrate. The substrate is etched using the solder dots to protect portions of the substrate and form cones in the substrate such that the cones provide a three-dimensional radiation absorbing structure for the photovoltaic device. | 03-06-2014 |
20140120655 | ENHANCING EFFICIENCY IN SOLAR CELLS BY ADJUSTING DEPOSITION POWER - Methods for forming a photovoltaic device include adjusting a deposition power for depositing a buffer layer including germanium on a transparent electrode. The deposition power is configured to improve device efficiency. A p-type layer is formed on the buffer layer. An intrinsic layer and an n-type layer are formed over the p-type layer. | 05-01-2014 |
20140124033 | UNIFORMLY DISTRIBUTED SELF-ASSEMBLED CONE-SHAPED PILLARS FOR HIGH EFFICIENCY SOLAR CELLS - A method for fabricating a photovoltaic device includes applying a diblock copolymer layer on a substrate and removing a first polymer material from the diblock copolymer layer to form a plurality of distributed pores. A pattern forming layer is deposited on a remaining surface of the diblock copolymer layer and in the pores in contact with the substrate. The diblock copolymer layer is lifted off and portions of the pattern forming layer are left in contact with the substrate. The substrate is etched using the pattern forming layer to protect portions of the substrate to form pillars in the substrate such that the pillars provide a radiation absorbing structure in the photovoltaic device. | 05-08-2014 |
20140124795 | DOUBLE LAYERED TRANSPARENT CONDUCTIVE OXIDE FOR REDUCED SCHOTTKY BARRIER IN PHOTOVOLTAIC DEVICES - A device and method for fabricating a photovoltaic device includes forming a double layer transparent conductive oxide on a transparent substrate. The double layer transparent conductive oxide includes forming a doped electrode layer on the substrate, and forming a buffer layer on the doped electrode layer. The buffer layer includes an undoped or p-type doped intrinsic form of a same material as the doped electrode layer. A light-absorbing semiconductor structure includes a p-type semiconductor layer on the buffer layer, an intrinsic layer and an n-type semiconductor layer. | 05-08-2014 |
20140127853 | DOUBLE LAYERED TRANSPARENT CONDUCTIVE OXIDE FOR REDUCED SCHOTTKY BARRIER IN PHOTOVOLTAIC DEVICES - A device and method for fabricating a photovoltaic device includes forming a double layer transparent conductive oxide on a transparent substrate. The double layer transparent conductive oxide includes forming a doped electrode layer on the substrate, and forming a buffer layer on the doped electrode layer. The buffer layer includes an undoped or p-type doped intrinsic form of a same material as the doped electrode layer. A light-absorbing semiconductor structure includes a p-type semiconductor layer on the buffer layer, an intrinsic layer and an n-type semiconductor layer. | 05-08-2014 |
20140216534 | BUFFER LAYER FOR HIGH PERFORMING AND LOW LIGHT DEGRADED SOLAR CELLS - Methods for forming a photovoltaic device include forming a buffer layer between a transparent electrode and a p-type layer. The buffer layer includes a doped germanium-free silicon base material. The buffer layer has a work function that falls within barrier energies of the transparent electrode and the p-type layer. An intrinsic layer and an n-type layer are formed on the p-type layer. Devices are also provided. | 08-07-2014 |
20140217408 | BUFFER LAYER FOR HIGH PERFORMING AND LOW LIGHT DEGRADED SOLAR CELLS - Methods for forming a photovoltaic device include forming a buffer layer between a transparent electrode and a p-type layer. The buffer layer includes a doped germanium-free silicon base material. The buffer layer has a work function that falls within barrier energies of the transparent electrode and the p-type layer. An intrinsic layer and an n-type layer are formed on the p-type layer. Devices are also provided. | 08-07-2014 |
20150075608 | PHOTOVOLTAIC DEVICE USING NANO-SPHERES FOR TEXTURED ELECTRODES - An electronic device includes a substrate and a plurality of particles anchored to the substrate. An electrode material is formed over the particles and configured to form peaks over the particles. One or more operational layers are formed over the electrode material for performing a device function. | 03-19-2015 |