Patent application number | Description | Published |
20110212622 | SURFACE TEXTURING USING A LOW QUALITY DIELECTRIC LAYER - A low cost method is described for forming a textured Si surface such as for a solar cell which includes forming a dielectric layer containing pinholes, anisotropically etching through the pinholes to form inverted pyramids in the Si surface and removing the dielectric layer thereby producing a high light trapping efficiency for incident radiation. | 09-01-2011 |
20120001283 | Germanium Photodetector - A method for forming a photodetector device includes forming an insulator layer on a substrate, forming a germanium (Ge) layer on the insulator layer and a portion of the substrate, forming a second insulator layer on the Ge layer, implanting n-type ions in the Ge layer, patterning the n-type Ge layer, forming a capping insulator layer on the second insulator layer and a portion of the first insulator layer, heating the device to crystallize the Ge layer resulting in an single crystalline n-type Ge layer, and forming electrodes electrically connected to the single crystalline n-type Ge layer. | 01-05-2012 |
20120288992 | Germanium Photodetector - A method for forming a photodetector device includes forming an insulator layer on a substrate, forming a germanium (Ge) layer on the insulator layer and a portion of the substrate, forming a second insulator layer on the Ge layer, patterning the Ge layer, forming a capping insulator layer on the second insulator layer and a portion of the first insulator layer, heating the device to crystallize the Ge layer resulting in an single crystalline Ge layer, implanting n-type ions in the single crystalline Ge layer, heating the device to activate n-type ions in the single crystalline Ge layer, and forming electrodes electrically connected to the single crystalline n-type Ge layer. | 11-15-2012 |
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 |
20140124019 | LOW VACUUM FABRICATION OF MICROCRYSTALLINE SOLAR CELLS - A device and method for forming a photovoltaic device include forming a photovoltaic stack of layers on a transparent substrate wherein at least one layer of the photovoltaic stack of layers includes a microcrystalline layer. The microcrystalline layer is formed by purging a vacuum chamber with a gettering gas to remove contaminant species from the chamber prior to forming the microcrystalline layer. The microcrystalline layer is deposited at a vacuum base pressure of greater than about 10 | 05-08-2014 |
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 |
20140127852 | LOW VACUUM FABRICATION OF MICROCRYSTALLINE SOLAR CELLS - A device and method for forming a photovoltaic device include forming a photovoltaic stack of layers on a transparent substrate wherein at least one layer of the photovoltaic stack of layers includes a microcrystalline layer. The microcrystalline layer is formed by purging a vacuum chamber with a gettering gas to remove contaminant species from the chamber prior to forming the microcrystalline layer. The microcrystalline layer is deposited at a vacuum base pressure of greater than about 10 | 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 |
20140134789 | Germanium Photodetector - A method for forming a photodetector device includes forming an insulator layer on a substrate, forming a germanium (Ge) layer on the insulator layer and a portion of the substrate, forming a second insulator layer on the Ge layer, patterning the Ge layer, forming a capping insulator layer on the second insulator layer and a portion of the first insulator layer, heating the device to crystallize the Ge layer resulting in an single crystalline Ge layer, implanting n-type ions in the single crystalline Ge layer, heating the device to activate n-type ions in the single crystalline Ge layer, and forming electrodes electrically connected to the single crystalline n-type Ge layer. | 05-15-2014 |
20140134790 | Germanium Photodetector - A method for forming a photodetector device includes forming an insulator layer on a substrate, forming a germanium (Ge) layer on the insulator layer and a portion of the substrate, forming a second insulator layer on the Ge layer, patterning the Ge layer, forming a capping insulator layer on the second insulator layer and a portion of the first insulator layer, heating the device to crystallize the Ge layer resulting in an single crystalline Ge layer, implanting n-type ions in the single crystalline Ge layer, heating the device to activate n-type ions in the single crystalline Ge layer, and forming electrodes electrically connected to the single crystalline n-type Ge layer. | 05-15-2014 |
20140144497 | ATOMIC LAYER DEPOSITION FOR PHOTOVOLTAIC DEVICES - A photovoltaic device and method include a substrate, a conductive layer formed on the substrate and an absorber layer formed on the conductive layer from a Cu—Zn—Sn containing chalcogenide material. An emitter layer is formed on the absorber layer and a buffer layer is formed on the emitter layer including an atomic layer deposition (ALD) layer. A transparent conductor layer is formed on the buffer layer. | 05-29-2014 |
20140147958 | ATOMIC LAYER DEPOSITION FOR PHOTOVOLTAIC DEVICES - A photovoltaic device and method include a substrate, a conductive layer formed on the substrate and an absorber layer formed on the conductive layer from a Cu—Zn—Sn containing chalcogenide material. An emitter layer is formed on the absorber layer and a buffer layer is formed on the emitter layer including an atomic layer deposition (ALD) layer. A transparent conductor layer is formed on the buffer layer. | 05-29-2014 |
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 |
20140217356 | THIN FILM WAFER TRANSFER AND STRUCTURE FOR ELECTRONIC DEVICES - An electronic device includes a spreading layer and a first contact layer formed over and contacting the spreading layer. The first contact layer is formed from a thermally conductive crystalline material having a thermal conductivity greater than or equal to that of an active layer material. An active layer includes one or more III-nitride layers. A second contact layer is formed over the active layer, wherein the active layer is disposed vertically between the first and second contact layers to form a vertical thin film stack. | 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 |
20140220764 | THIN FILM WAFER TRANSFER AND STRUCTURE FOR ELECTRONIC DEVICES - A method for wafer transfer includes forming a spreading layer, including graphene, on a single crystalline SiC substrate. A semiconductor layer including one or more layers is formed on and is lattice matched to the crystalline SiC layer. The semiconductor layer is transferred to a handle substrate, and the spreading layer is split to remove the single crystalline SiC substrate. | 08-07-2014 |
20140284547 | SELF-FORMATION OF HIGH-DENSITY ARRAYS OF NANOSTRUCTURES - A method for forming nanostructures includes bonding a flexible substrate to a crystalline semiconductor layer having a two-dimensional material formed on a side opposite the flexible substrate. The crystalline semiconductor layer is stressed in a first direction to initiate first cracks in the crystalline semiconductor layer. The first cracks are propagated through the crystalline semiconductor layer and through the two-dimensional material. The stress of the crystalline semiconductor layer is released to provide parallel structures including the two-dimensional material on the crystalline semiconductor layer. | 09-25-2014 |
20140284616 | SELF-FORMATION OF HIGH-DENSITY ARRAYS OF NANOSTRUCTURES - A method for forming nanostructures includes bonding a flexible substrate to a crystalline semiconductor layer having a two-dimensional material formed on a side opposite the flexible substrate. The crystalline semiconductor layer is stressed in a first direction to initiate first cracks in the crystalline semiconductor layer. The first cracks are propagated through the crystalline semiconductor layer and through the two-dimensional material. The stress of the crystalline semiconductor layer is released to provide parallel structures including the two-dimensional material on the crystalline semiconductor layer. | 09-25-2014 |
20140291282 | WAFER SCALE EPITAXIAL GRAPHENE TRANSFER - A method for transfer of a two-dimensional material includes forming a spreading layer of a two-dimensional material on a substrate, the spreading layer having a monolayer. A stressor layer is formed on the spreading layer, and the stressor layer is configured to apply stress to a closest monolayer of the spreading layer. The closest monolayer is exfoliated by mechanically splitting the spreading layer wherein the closest monolayer remains on the stressor layer. | 10-02-2014 |
20140305499 | PROTECTIVE INSULATING LAYER AND CHEMICAL MECHANICAL POLISHING FOR POLYCRYSTALLINE THIN FILM SOLAR CELLS - A method for forming a photovoltaic device includes forming an absorber layer with a granular structure on a conductive layer; conformally depositing an insulating protection layer over the absorber layer to fill in between grains of the absorber layer; and planarizing the protection layer and the absorber layer. A buffer layer is formed on the absorber layer, and a top transparent conductor layer is deposited over the buffer layer. | 10-16-2014 |
20140306306 | PROTECTIVE INSULATING LAYER AND CHEMICAL MECHANICAL POLISHING FOR POLYCRYSTALLINE THIN FILM SOLAR CELLS - A method for forming a photovoltaic device includes forming an absorber layer with a granular structure on a conductive layer; conformally depositing an insulating protection layer over the absorber layer to fill in between grains of the absorber layer; and planarizing the protection layer and the absorber layer. A buffer layer is formed on the absorber layer, and a top transparent conductor layer is deposited over the buffer layer. | 10-16-2014 |
20140339506 | FORMATION OF LARGE SCALE SINGLE CRYSTALLINE GRAPHENE - A method for transfer of a two-dimensional material includes forming a spreading layer of a two-dimensional material on a first substrate. The spreading layer has at least one monolayer. A stressor layer is formed on the spreading layer. The stressor layer is configured to apply stress to a closest monolayer of the spreading layer. The closest monolayer is exfoliated by mechanically splitting the spreading layer wherein at least the closest monolayer remains on the stressor layer. The at least one monolayer is stamped against a second substrate to adhere remnants of the two-dimensional material on the at least one monolayer to the second substrate to provide a single monolayer on the stressor layer. The single monolayer is transferred to a third substrate. | 11-20-2014 |
20140342127 | FORMATION OF LARGE SCALE SINGLE CRYSTALLINE GRAPHENE - A method for transfer of a two-dimensional material includes forming a spreading layer of a two-dimensional material on a first substrate. The spreading layer has at least one monolayer. A stressor layer is formed on the spreading layer. The stressor layer is configured to apply stress to a closest monolayer of the spreading layer. The closest monolayer is exfoliated by mechanically splitting the spreading layer wherein at least the closest monolayer remains on the stressor layer. The at least one monolayer is stamped against a second substrate to adhere remnants of the two-dimensional material on the at least one monolayer to the second substrate to provide a single monolayer on the stressor layer. The single monolayer is transferred to a third substrate. | 11-20-2014 |
20150027521 | LOW REFLECTION ELECTRODE FOR PHOTOVOLTAIC DEVICES - A method for forming a photovoltaic device includes forming a photovoltaic absorption stack on a substrate including one or more of I-III-VI | 01-29-2015 |
20150028279 | RESISTIVE RANDOM ACCESS MEMORY DEVICES WITH EXTREMELY REACTIVE CONTACTS - A resistive switching device includes a first electrode and a transition metal oxide layer formed on the first electrode. An oxygen scavenging electrode is formed on the transition metal oxide wherein the oxygen scavenging electrode removes oxygen from the transition metal oxide layer to increase formation of oxygen vacancies in the transition metal oxide layer to enable a switching mode when a bias is applied between the first electrode and the oxygen scavenging electrode. | 01-29-2015 |
20150083036 | GALLIUM NITRIDE MATERIAL AND DEVICE DEPOSITION ON GRAPHENE TERMINATED WAFER AND METHOD OF FORMING THE SAME - A method of forming an epitaxial semiconductor material that includes forming a graphene layer on a semiconductor and carbon containing substrate and depositing a metal containing monolayer on the graphene layer. An epitaxial layer of a gallium containing material is formed on the metal containing monolayer. A layered stack of the metal containing monolayer and the epitaxial layer of gallium containing material is cleaved from the graphene layer that is present on the semiconductor and carbon containing substrate. | 03-26-2015 |
20150083224 | TRANSFERABLE TRANSPARENT CONDUCTIVE OXIDE - A method for fabricating a photovoltaic device includes forming an adhesion layer on a substrate, forming a material layer on the adhesion layer and applying release tape to the material layer. The substrate is removed at a weakest interface between the adhesion layer and the substrate by mechanically pulling the release tape to form a transfer substrate including the adhesion layer, the material layer and the release tape. The transfer substrate is transferred to a target substrate to contact the adhesion layer to the target substrate. The transfer substrate includes a material sensitive to formation processes of the transfer substrate such that exposure to the formation processes of the transfer substrate is avoided by the target substrate. | 03-26-2015 |
20150084004 | TRANSFERABLE TRANSPARENT CONDUCTIVE OXIDE - A method for fabricating a photovoltaic device includes forming an adhesion layer on a substrate, forming a material layer on the adhesion layer and applying release tape to the material layer. The substrate is removed at a weakest interface between the adhesion layer and the substrate by mechanically pulling the release tape to form a transfer substrate including the adhesion layer, the material layer and the release tape. The transfer substrate is transferred to a target substrate to contact the adhesion layer to the target substrate. The transfer substrate includes a material sensitive to formation processes of the transfer substrate such that exposure to the formation processes of the transfer substrate is avoided by the target substrate. | 03-26-2015 |
20150084074 | GALLIUM NITRIDE MATERIAL AND DEVICE DEPOSITION ON GRAPHENE TERMINATED WAFER AND METHOD OF FORMING THE SAME - A method of forming an epitaxial semiconductor material that includes forming a graphene layer on a semiconductor and carbon containing substrate and depositing a metal containing monolayer on the graphene layer. An epitaxial layer of a gallium containing material is formed on the metal containing monolayer. A layered stack of the metal containing monolayer and the epitaxial layer of gallium containing material is cleaved from the graphene layer that is present on the semiconductor and carbon containing substrate. | 03-26-2015 |