Patent application number | Description | Published |
20090325362 | METHOD OF RECYCLING AN EPITAXIED DONOR WAFER - A method for forming a semiconductor structure that includes a thin layer of semiconductor material on a receiver wafer is disclosed. The method includes removing a thickness of material from a donor wafer, which comprises a support substrate and an epitaxial layer, for surface preparation and transferring a portion of the epitaxial layer from the donor wafer to the receiver wafer. The thickness removed during the surface preparation is adapted to enable formation of a new semiconductor structure from the remaining epitaxial portion of the donor wafer. | 12-31-2009 |
20100096733 | PROCESS FOR FABRICATING A SUBSTRATE COMPRISING A DEPOSITED BURIED OXIDE LAYER - A process for fabricating a substrate that includes a buried oxide layer for the production of electronic components or the like. The process includes depositing an oxide layer or a nitride layer on either of a donor or receiver substrate, and bringing the donor and receiver substrates into contact; conducting at least a first heat treatment of the oxide or nitride layer before bonding the substrates, and conducting a second heat treatment of the fabricated substrate of the receiver substrate, the oxide layer and all or part of the donor substrate at a temperature equal to or higher than the temperature applied in the first heat treatment. Substrates that have an oxide or nitride layer deposited thereon wherein the oxide or nitride layer is degassed and has a refractive index smaller than the refractive index of an oxide or nitride layer of the same composition formed by thermal growth. | 04-22-2010 |
20100167500 | METHOD OF RECYCLING AN EPITAXIED DONOR WAFER - A method for forming a semiconductor structure that includes a thin layer of semiconductor material on a receiver wafer is disclosed. The method includes removing a thickness of material from a donor wafer, which comprises a support substrate and an epitaxial layer, for surface preparation and transferring a portion of the epitaxial layer from the donor wafer to the receiver wafer. The thickness removed during the surface preparation is adapted to enable formation of a new semiconductor structure from the remaining epitaxial portion of the donor wafer. | 07-01-2010 |
20110183493 | PROCESS FOR MANUFACTURING A STRUCTURE COMPRISING A GERMANIUM LAYER ON A SUBSTRATE - The present invention relates to a process for manufacturing a structure comprising a germanium layer ( | 07-28-2011 |
20110193201 | METHOD TO FABRICATE AND TREAT A STRUCTURE OF SEMICONDUCTOR-ON-INSULATOR TYPE, ENABLING DISPLACEMENT OF DISLOCATIONS, AND CORRESPONDING STRUCTURE - The present invention notably concerns a method to fabricate and treat a structure of semiconductor-on-insulator type, successively comprising a carrier substrate ( | 08-11-2011 |
20110275226 | PROCESS TO DISSOLVE THE OXIDE LAYER IN THE PERIPHERAL RING OF A STRUCTURE OF SEMICONDUCTOR-ON-INSULATOR TYPE - The invention concerns a process to treat a structure of semiconductor-on-insulator type structure of a carrier substrate, an oxide layer and a thin layer of a semiconductor material, wherein the structure having a peripheral ring in which the oxide layer is exposed, and the process includes the application of a main thermal treatment in a neutral or controlled reducing atmosphere. The method includes a step to cover at least an exposed peripheral part of the oxide layer, prior to the main thermal treatment, this latter treatment being conducted under controlled time and temperature conditions so as to urge at least part of the oxygen in the oxide layer to diffuse through the thin semiconductor layer, leading to controlled reduction of the thickness of the oxide layer. | 11-10-2011 |
20120094496 | Process For Locally Dissolving The Oxide Layer In A Semiconductor-On-Insulator Type Structure - A process for treating a semiconductor-on-insulator type structure that includes, successively, a support substrate, an oxide layer and a thin semiconductor layer. The process includes formation of a silicon nitride or silicon oxynitride mask on the thin semiconductor layer to define exposed areas at the surface of the layer which are not covered by the mask, and which are arranged in a desired pattern; and application of a heat treatment in a neutral or controlled reducing atmosphere and under controlled conditions of temperature and time to induce at least a portion of the oxygen of the oxide layer to diffuse through the thin semiconductor layer, thereby resulting in the controlled reduction in the oxide thickness in the areas of the oxide layer corresponding to the desired pattern. The mask is formed so as to be at least partially buried in the thickness of the thin semiconductor layer. | 04-19-2012 |
20140030877 | PROCESS TO DISSOLVE THE OXIDE LAYER IN THE PERIPHERAL RING OF A STRUCTURE OF SEMICONDUCTOR-ON-INSULATOR TYPE - A process for avoiding formation of a Si—SiO | 01-30-2014 |
20160043254 | MULTIPLE TRANSFER ASSEMBLY PROCESS - This disclosure is related to a manufacturing method for a plurality of photovoltaic cells comprising the steps of: obtaining a plurality of photovoltaic cells placed at a first distance from each other; attaching a stretching material to the plurality of photovoltaic cells; and stretching the stretching material such that the plurality of photovoltaic cells result at a second distance from each other, wherein the second distance is greater that the first distance. | 02-11-2016 |
20160056318 | ADVANCED CPV SOLAR CELL ASSEMBLY PROCESS - This disclosure relates to a solar cell assembly structure for supporting a concentrator photovoltaic cell structure (3420), comprising a semiconducting structure and a diode, wherein the semiconducting structure comprises a first semiconducting region at least a part of which for placing the concentrator photovoltaic cell structure, and a second semiconducting region for realizing the diode within or on the second semiconducting region and wherein the part of the first semiconducting region for placing the concentrator photovoltaic cell structure and the second semiconducting region are not vertically overlapping. | 02-25-2016 |