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Devendra Sadana

Devendra Sadana, Yorktown Heights, NY US

Patent application number	Description	Published
20100307572	Heterojunction III-V Photovoltaic Cell Fabrication - A method for forming a heterojunction III-V photovoltaic (PV) cell includes performing layer transfer of a base layer from a wafer of a III-V substrate, the base layer being less than about 20 microns thick; forming an intrinsic layer on the base layer; forming an amorphous silicon layer on the intrinsic layer; and forming a transparent conducting oxide layer on the amorphous silicon layer. A heterojunction III-V photovoltaic (PV) cell includes a base layer comprising a III-V substrate, the base layer being less than about 20 microns thick; an intrinsic layer located on the base layer; an amorphous silicon layer located on the intrinsic layer; and a transparent conducting oxide layer located on the amorphous silicon layer.	12-09-2010
20100307591	Single-Junction Photovoltaic Cell - A method for forming a single-junction photovoltaic cell includes forming a dopant layer on a surface of a semiconductor substrate; diffusing the dopant layer into the semiconductor substrate to form a doped layer of the semiconductor substrate; forming a metal layer over the doped layer, wherein a tensile stress in the metal layer is configured to cause a fracture in the semiconductor substrate; removing a semiconductor layer from the semiconductor substrate at the fracture; and forming the single junction photovoltaic cell using the semiconductor layer. A single-junction photovoltaic cell includes a doped layer comprising a dopant diffused into a semiconductor substrate; a patterned conducting layer formed on the doped layer; a semiconductor layer comprising the semiconductor substrate located on the doped layer on a surface of the doped layer opposite the patterned conducting layer; and an ohmic contact layer formed on the semiconductor layer.	12-09-2010
20100310775	Spalling for a Semiconductor Substrate - A method for spalling a layer from an ingot of a semiconductor substrate includes forming a metal layer on the ingot of the semiconductor substrate, wherein a tensile stress in the metal layer is configured to cause a fracture in the ingot; and removing the layer from the ingot at the fracture. A system for spalling a layer from an ingot of a semiconductor substrate includes a metal layer formed on the ingot of the semiconductor substrate, wherein a tensile stress in the metal layer is configured to cause a fracture in the ingot, and wherein the layer is configured to be removed from the ingot at the fracture.	12-09-2010
20110048516	Multijunction Photovoltaic Cell Fabrication - A method for fabrication of a multijunction photovoltaic (PV) cell includes providing a stack comprising a plurality of junctions on a substrate, each of the plurality of junctions having a respective bandgap, wherein the plurality of junctions are ordered from the junction having the smallest bandgap being located on the substrate to the junction having the largest bandgap being located on top of the stack; forming a top metal layer, the top metal layer having a tensile stress, on top of the junction having the largest bandgap; adhering a top flexible substrate to the metal layer; and spalling a semiconductor layer from the substrate at a fracture in the substrate, wherein the fracture is formed in response to the tensile stress in the top metal layer.	03-03-2011
20110048517	Multijunction Photovoltaic Cell Fabrication - A method for fabrication of a multijunction photovoltaic (PV) cell includes forming a stack comprising a plurality of junctions on a substrate, each of the plurality of junctions having a respective bandgap, wherein the plurality of junctions are ordered from the junction having the largest bandgap being located on the substrate to the junction having the smallest bandgap being located on top of the stack; forming a metal layer, the metal layer having a tensile stress, on top of the junction having the smallest bandgap; adhering a flexible substrate to the metal layer; and spalling a semiconductor layer from the substrate at a fracture in the substrate, wherein the fracture is formed in response to the tensile stress in the metal layer.	03-03-2011

Devendra Sadana, Armonk, NY US

Patent application number	Description	Published
20100311250	THIN SUBSTRATE FABRICATION USING STRESS-INDUCED SUBSTRATE SPALLING - A method for manufacturing a thin film direct bandgap semiconductor active solar cell device comprises providing a source substrate having a surface and disposing on the surface a stress layer having a stress layer surface area in contact with and bonded to the surface of the source substrate. Operatively associating a handle foil with the stress layer and applying force to the handle foil separates the stress layer from the source substrate, and leaves a portion of the source substrate on the stress layer surface substantially corresponding to the area in contact with the surface of the source substrate. The portion is less thick than the source layer. The stress layer thickness is below that which results in spontaneous spalling of the source substrate. The source substrate may comprise an inorganic single crystal or polycrystalline material such as Si, Ge, GaAs, SiC, sapphire, or GaN. In one embodiment the stress layer comprises a flexible material.	12-09-2010

Devendra Sadana, Pleasantville, NY US

Patent application number	Description	Published
20080206965	STRAINED SILICON MADE BY PRECIPITATING CARBON FROM Si(1-x-y)GexCy ALLOY - Disclosed herein is a method of preparing strained silicon comprising annealing a carbon-doped silicon-germanium (SiGe:C) alloy containing region disposed adjacent to a silicon region, wherein the lattice constant of the SiGe:C alloy after annealing is greater than that of the SiGe:C alloy prior to annealing. The method can be used to prepare articles including metal oxide semiconductor field effect transistor (MOSFET) devices.	08-28-2008
20100006985	FORMATION OF SOI BY OXIDATION OF SILICON WITH ENGINEERED POROSITY GRADIENT - A method is provided for making a silicon-on-insulator substrate. Such method can include epitaxially growing a highly p-type doped silicon-containing layer onto a major surface of an underlying semiconductor region of a substrate. Subsequently, a non-highly p-type doped silicon-containing layer may be epitaxially grown onto a major surface of the p-type highly-doped epitaxial layer to cover the highly p-type doped epitaxial layer. The overlying non-highly p-type doped epitaxial layer can have a dopant concentration substantially lower than the dopant concentration of the highly p-type doped epitaxial layer. The substrate can then be processed to form a buried oxide layer selectively by oxidizing at least portions of the highly p-type doped epitaxial layer covered by the non-highly p-type doped epitaxial layer, the buried oxide layer separating the overlying monocrystalline semiconductor layer from the underlying semiconductor region. Such processing can be performed while simultaneously annealing the non-highly p-type doped epitaxial layer.	01-14-2010
20110147809	FORMING A CARBON CONTAINING LAYER TO FACILITATE SILICIDE STABILITY IN A SILICON GERMANIUM MATERIAL - A method includes forming a silicon germanium layer, forming a layer comprising carbon and silicon on a top surface of the silicon germanium layer, forming a metal layer above the layer comprising carbon and silicon, and performing a thermal treatment to convert at least the layer comprising carbon and silicon to form a metal silicide layer.	06-23-2011