Abstract: Methods for preparing layered semiconductor structures are disclosed. The methods may involve pretreating an ion-implanted donor wafer by annealing the ion-implanted donor wafer to cause a portion of the ions to out-diffuse prior to wafer bonding. The donor structure may be bonded to a handle structure and cleaved without re-implanting ions into the donor structure.

Abstract: Methods for preparing layered semiconductor structures are disclosed. The methods may involve pretreating an ion-implanted donor wafer by annealing the ion-implanted donor wafer to cause a portion of the ions to out-diffuse prior to wafer bonding. The donor structure may be bonded to a handle structure and cleaved without re-implanting ions into the donor structure.

Abstract: Methods and systems are disclosed for performing a passivation process on a silicon-on-insulator wafer in a chamber in which the wafer is cleaved. A bonded wafer pair is cleaved within the chamber to form the silicon-on-insulator (SOI) wafer. A cleaved surface of the SOI wafer is then passivated in-situ by exposing the cleaved surface to a passivating substance. This exposure to a passivating substance results in the formation of a thin layer of oxide on the cleaved surface. The silicon-on-insulator wafer is then removed from the chamber. In other embodiments, the silicon-on-insulator wafer is first transferred to an adjoining chamber where the wafer is then passivated. The wafer is transferred to the adjoining chamber without exposing the wafer to the atmosphere outside the chambers.

Abstract: Methods and systems are disclosed for performing a passivation process on a silicon-on-insulator wafer in a chamber in which the wafer is cleaved. A bonded wafer pair is cleaved within the chamber to form the silicon-on-insulator (SOI) wafer. A cleaved surface of the SOI wafer is then passivated in-situ by exposing the cleaved surface to a passivating substance. This exposure to a passivating substance results in the formation of a thin layer of oxide on the cleaved surface. The silicon-on-insulator wafer is then removed from the chamber. In other embodiments, the silicon-on-insulator wafer is first transferred to an adjoining chamber where the wafer is then passivated. The wafer is transferred to the adjoining chamber without exposing the wafer to the atmosphere outside the chambers.

Abstract: A method is disclosed for processing the cleaved surface of a silicon-on-insulator structure. The silicon-on-insulator structures comprises a handle wafer, a silicon layer, and a dielectric layer between the handle wafer and the silicon layer. The silicon layer has a cleaved surface defining an outer surface of the structure. The methods disclosed include an etching process to reduce the time and cost required to process the silicon-on-insulator structure to remove the surface damage and defects formed when a portion of the donor wafer is separated along a cleave plane from the silicon-on-insulator structure. The method includes, annealing the structure, etching the cleaved surface, and performing a non-contact smoothing process on the cleaved surface.

Abstract: A single crystal silicon wafer with a back surface free of an oxide seal and substantially free of a chemical vapor deposition process induced halo and an epitaxial silicon layer on the front surface, the epitaxial layer is characterized by an axially symmetric region extending radially outwardly from the central axis of the wafer toward the circumferential edge of the wafer having a substantially uniform resistivity, the radius of the axially symmetric region being at least about 80% of the length of the radius of the wafer.

Abstract: A holder for holding a semiconductor wafer for treatment in wafer treating apparatus including a plurality of supports for generally point support of the wafer at a plurality of points on the wafer. Each support bears a fraction of weight of the wafer and is movable up and down and subject to force biasing it to move upward. The total of the forces exerted on the supports biasing them upward is adapted to counterbalance the weight of the wafer.

Abstract: The process relates to a process for nucleating and growing oxygen precipitates in a silicon wafer. The process includes subjecting a wafer having a non-uniform concentration of crystal lattice vacancies with the concentration of vacancies in the bulk layer being greater than the concentration of vacancies in the surface layer to a non-isothermal heat treatment to form of a denuded zone in the surface layer and to cause the formation and stabilization of oxygen precipitates having an effective radial size 0.5 nm to 30 nm in the bulk layer. The process optionally includes subjecting the stabilized wafer to a high temperature thermal process (e.g. epitaxial deposition, rapid thermal oxidation, rapid thermal nitridation and etc.) at temperatures in the range of 1000° C. to 1275° C. without causing the dissolution of the stabilized oxygen precipitates.

Abstract: A process for manufacturing a semiconductor wafer comprises first etching the wafer to reduce damage on the front and back surfaces. An epitaxial layer is grown on the etched front surface of the semiconductor wafer to improve the surface roughness of the front surface. Finally, the front surface of the wafer is final polished to further improve the surface roughness of the front surface.

Abstract: A holder for holding a semiconductor wafer for treatment in wafer treating apparatus including a plurality of supports for generally point support of the wafer at a plurality of points on the wafer. Each support bears a fraction of weight of the wafer and is movable up and down and subject to force biasing it to move upward. The total of the forces exerted on the supports biasing them upward is adapted to counterbalance the weight of the wafer.

Abstract: An apparatus and method are provided for forming a denuded zone and an epitaxial layer on a semiconductor wafer used in manufacturing electronic components. The denuded zone and epitaxial layer are formed in one chamber. The apparatus includes a plurality of upstanding pins immovably mounted on a susceptor and maintain a semiconductor wafer spaced from the susceptor during both application of the epitaxial layer and formation of the denuded zone. Fast cooling of the wafer is accomplished by having the wafer out of conductive heat transfer relation with the susceptor during cooling thereof.

Abstract: A single crystal silicon wafer with a back surface free of an oxide seal and substantially free of a chemical vapor deposition process induced halo and an epitaxial silicon layer on the front surface, the epitaxial layer is characterized by an axially symmetric region extending radially outwardly from the central axis of the wafer toward the circumferential edge of the wafer having a substantially uniform resistivity, the radius of the axially symmetric region being at least about 80% of the length of the radius of the wafer.

Abstract: A system for equalizing pressure across a gate adapted to selectively block a port connecting a wafer handling chamber to a process chamber of a reactor for depositing an epitaxial layer on a semiconductor wafer positioned in the process chamber. The system comprises a bypass passage connecting the process chamber to the wafer handling chamber for transporting gas between the process chamber and the wafer handling chamber when the gate is blocking the port connecting the wafer handling chamber to the process chamber of the reactor for equalizing pressure between the process chamber and the wafer handling chamber. The system also includes a bypass valve positioned along the bypass passage for selectively controlling gas flow through the bypass passage.

Abstract: A horizontal reactor for depositing an epitaxial layer on a semiconductor wafer. The reactor includes a reaction chamber sized and shaped for receiving the semiconductor wafer and a susceptor having an outer edge and a generally planar wafer receiving surface positioned in the reaction chamber for supporting the semiconductor wafer. In addition, the reactor includes a heating array positioned outside the reaction chamber including a plurality of heat lamps and a primary reflector for directing thermal radiation emitted by the heat lamps toward the susceptor to heat the semiconductor wafer and susceptor. Further, the reactor includes a secondary edge reflector having a specular surface positioned beside the heating array for recovering misdirected thermal radiation directed generally to a side of the heating array and away from the susceptor.