Abstract: A method is provided for preparing a high resistivity silicon handle substrate for use in semiconductor-on-insulator structure. The handle substrate is prepared to comprise thermally stable charge carrier traps in the region of the substrate that will be at or near the buried oxide layer (BOX) of the final semiconductor-on-insulator structure. The handle substrate comprising the stable carrier traps is manufactured by hydrogen ions implantation occurring using at least two different energies, followed by a 2-step thermal treatment. The thermally stable defect structures prepared thereby is stable to anneal at temperatures of at least 1180° C. The defect structure comprises 3-dimensional network of nano-cavities interconnected by dislocations. This wafer can be used as a handle wafer for fabricating silicon-on-insulator (SOI) wafers and further fabricating radio frequency (RF) semiconductor devices.

Abstract: A semiconductor on insulator multilayer structure is provided. The multilayer comprises a high resistivity single crystal semiconductor handle substrate, an optionally relaxed semiconductor layer comprising silicon, germanium, or silicon germanium, an optional polycrystalline silicon layer, a dielectric layer, and a single crystal semiconductor device layer.

Abstract: Methods for preparing silicon-on-insulator structures and related intermediate structures are disclosed. In some embodiments, a single crystal silicon seed crystal is bonded to an amorphous silicon layer disposed on a substrate and the amorphous layer is crystallized to form a monocrystalline silicon layer.

Abstract: A method is provided for preparing a high resistivity silicon handle substrate for use in semiconductor-on-insulator structure. The handle substrate is prepared to comprise thermally stable charge carrier traps in the region of the substrate that will be at or near the buried oxide layer (BOX) of the final semiconductor-on-insulator structure. The handle substrate comprising the stable carrier traps is manufactured by hydrogen ions implantation occurring using at least two different energies, followed by a 2-step thermal treatment. The thermally stable defect structures prepared thereby is stable to anneal at temperatures of at least 1180° C. The defect structure comprises 3-dimensional network of nano-cavities interconnected by dislocations. This wafer can be used as a handle wafer for fabricating silicon-on-insulator (SOI) wafers and further fabricating radio frequency (RF) semiconductor devices.

Abstract: A process for preparing a surface of a material that is not bondable to make it bondable to the surface of another material. A non-bondable surface of a semiconductor wafer is treated with oxygen plasma to oxidize the surface of the wafer and make the surface smoother, hydrophilic and bondable to the surface of another substrate, such as a glass substrate. The semiconductor wafer may have a barrier layer thereon formed of a material, such as SixNy or SiNxOy that is not bondable to another substrate, such as a glass substrate. In which case, the oxygen plasma treatment converts the surface of the barrier layer to oxide, such as SiO2, smoothing the surface and making the surface hydrophilic and bondable to the surface of another substrate, such as a glass substrate.

Abstract: A process of making semiconductor-on-glass substrates having a relatively stiff (e.g. relatively high Young's modulus of 125 or higher) stiffening layer between the silicon film and the glass in an ion implantation thin film transfer process by depositing a stiffening layer or layers on one of the donor wafer or the glass substrate in order to eliminate the canyons and pin holes that otherwise form in the surface of the transferred silicon film during the thin film transfer process. The new stiffening layer may be formed of a material, such as silicon nitride, that also serves as an efficient barrier against penetration of sodium and other harmful impurities from the glass substrate into the silicon film.

Abstract: A semiconductor-on-glass substrate having a relatively stiff (e.g. relatively high Young's modulus of 125 or higher) stiffening layer or layers placed between the silicon film and the glass in order to eliminate the canyons and pin holes that otherwise form in the surface of the transferred silicon film during the ion implantation thin film transfer process. The new stiffening layer may be formed of a material, such as silicon nitride, that also serves as an efficient barrier against penetration of sodium and other harmful impurities from the glass substrate into the silicon film.

Abstract: A process for finishing an as transferred layer on a semiconductor-on-insulator structure or a semiconductor-on-glass (or other insulator substrate) structure is provided by removing the damaged surface portion of a semiconductor layer while a leaving a smooth, finished semiconductor film on the glass. The damaged surface layer is treated with an oxygen plasma to oxidize the damaged layer and convert the damaged layer into an oxide layer. The oxide layer is then stripped in a wet bath, such as hydrofluoric acid bath, thereby removing the damaged portion of the semiconductor layer. The damaged layer may be an ion implantation damaged layer resulting from a thin film transfer processes used to make the semiconductor-on-insulator structure or the semiconductor-on-glass structure.

Abstract: A semiconductor-on-glass substrate having a relatively stiff (e.g. relatively high Young's modulus of 125 or higher) stiffening layer or layers placed between the silicon film and the glass in order to eliminate the canyons and pin holes that otherwise form in the surface of the transferred silicon film during the ion implantation thin film transfer process. The new stiffening layer may be formed of a material, such as silicon nitride, that also serves as an efficient barrier against penetration of sodium and other harmful impurities from the glass substrate into the silicon film.

Abstract: Methods and apparatus provide for forming a semiconductor-on-insulator (SOI) structure, including subjecting a implantation surface of a donor semiconductor wafer to an ion implantation step to create a weakened slice in cross-section defining an exfoliation layer of the donor semiconductor wafer; and subjecting the donor semiconductor wafer to a spatial variation step, either before, during or after the ion implantation step, such that at least one parameter of the weakened slice varies spatially across the weakened slice in at least one of X- and Y- axial directions.

Abstract: The invention relates to methods of making unsupported articles of semiconducting material using thermally active molds having an external surface temperature, Tsurface, and a core temperature, Tcore, whererin Tsurface>Tcore.

Abstract: Methods and apparatus provide for forming a semiconductor-on-insulator (SOI) structure, including subjecting a implantation surface of a donor semiconductor wafer to an ion implantation step to create a weakened slice in cross-section defining an exfoliation layer of the donor semiconductor wafer; and subjecting the donor semiconductor wafer to a spatial variation step, either before, during or after the ion implantation step, such that at least one parameter of the weakened slice varies spatially across the weakened slice in at least one of X- and Y- axial directions.

Abstract: A process for preparing a surface of a material that is not bondable to make it bondable to the surface of another material. A non-bondable surface of a semiconductor wafer is treated with oxygen plasma to oxidize the surface of the wafer and make the surface smoother, hydrophilic and bondable to the surface of another substrate, such as a glass substrate. The semiconductor wafer may have a barrier layer thereon formed of a material, such as SixNy or SiNxOy that is not bondable to another substrate, such as a glass substrate. In which case, the oxygen plasma treatment converts the surface of the barrier layer to oxide, such as SiO2, smoothing the surface and making the surface hydrophilic and bondable to the surface of another substrate, such as a glass substrate.

Abstract: A semiconductor-on-glass substrate having a relatively stiff (e.g. relatively high Young's modulus of 125 or higher) stiffening layer or layers placed between the silicon film and the glass in order to eliminate the canyons and pin holes that otherwise form in the surface of the transferred silicon film during the ion implantation thin film transfer process. The new stiffening layer may be formed of a material, such as silicon nitride, that also serves as an efficient barrier against penetration of sodium and other harmful impurities from the glass substrate into the silicon film.

Abstract: Methods and apparatus provide for forming a semiconductor-on-insulator (SOI) structure, including subjecting a implantation surface of a donor semiconductor wafer to an ion implantation step to create a weakened slice in cross-section defining an exfoliation layer of the donor semiconductor wafer; and subjecting the donor semiconductor wafer to a spatial variation step, either before, during or after the ion implantation step, such that at least one parameter of the weakened slice varies spatially across the weakened slice in at least one of X- and Y-axial directions.

Abstract: Methods and apparatus provide for forming a semiconductor-on-insulator (SOI) structure, including subjecting a implantation surface of a donor semiconductor wafer to an ion implantation step to create a weakened slice in cross-section defining an exfoliation layer of the donor semiconductor wafer; and subjecting the donor semiconductor wafer to a spatial variation step, either before, during or after the ion implantation step, such that at least one parameter of the weakened slice varies spatially across the weakened slice in at least one of X- and Y-axial directions.

Abstract: Methods and apparatus provide for forming a semiconductor-on-insulator (SOI) structure, including subjecting a implantation surface of a donor semiconductor wafer to an ion implantation step to create a weakened slice in cross-section defining an exfoliation layer of the donor semiconductor wafer; and subjecting the donor semiconductor wafer to a spatial variation step, either before, during or after the ion implantation step, such that at least one parameter of the weakened slice varies spatially across the weakened slice in at least one of X-and Y-axial directions.

Abstract: Methods and apparatus provide for forming a semiconductor-on-insulator (SOI) structure, including subjecting a implantation surface of a donor semiconductor wafer to an ion implantation step to create a weakened slice in cross-section defining an exfoliation layer of the donor semiconductor wafer; and subjecting the donor semiconductor wafer to a spatial variation step, either before, during or after the ion implantation step, such that at least one parameter of the weakened slice varies spatially across the weakened slice in at least one of X- and Y-axial directions.

Abstract: Methods and apparatus for producing a semiconductor on glass (SOG) structure include: subjecting an implantation surface of a donor semiconductor wafer to an ion implantation process to create an exfoliation layer of the donor semiconductor wafer; bonding the implantation surface of the exfoliation layer to a glass substrate using electrolysis; separating the exfoliation layer from the donor semiconductor wafer, thereby exposing at least one cleaved surface; subjecting the at least one cleaved surface to an amorphization ion implantation process at a dose sufficient to amorphize at least some depth of the semiconductor material below the at least one cleaved surface; and re-growing the amorphized portion of the semiconductor material into a substantially single crystalline semiconductor layer using solid phase epitaxial re-growth

Abstract: Methods and apparatus provide for forming a semiconductor-on-insulator (SOI) structure, including subjecting a implantation surface of a donor semiconductor wafer to an ion implantation step to create a weakened slice in cross-section defining an exfoliation layer of the donor semiconductor wafer; and subjecting the donor semiconductor wafer to a spatial variation step, either before, during or after the ion implantation step, such that at least one parameter of the weakened slice varies spatially across the weakened slice in at least one of X- and Y-axial directions.