Abstract: Disclosed herein are devices, methods and systems for ex-situ component recovery. The ex-situ recovery can be performed by desorbing or outgassing components of a processing system in a recovery system, rather than in the processing system itself. The recovery system can include a docking station and/or a heated vacuum chamber. The heated vacuum chamber can be used to desorb or outgas components that will be located inside the processing system, while the docking station can be used to desorb or outgas components that will be connected to the processing system. The processing system components can be placed under pressure by the recovery system to desorb or outgas contaminants and remove virtual leaks. The recovery system pressure can include a vacuum roughing pump, a turbomolecular pump, and/or a cryogenic pump to apply a pressure necessary to desorb or outgas the components.

Abstract: Disclosed herein are devices, methods and systems for ex-situ component recovery. The ex-situ recovery can be performed by desorbing or outgassing components of a processing system in a recovery system, rather than in the processing system itself. The recovery system can include a docking station and/or a heated vacuum chamber. The heated vacuum chamber can be used to desorb or outgas components that will be located inside the processing system, while the docking station can be used to desorb or outgas components that will be connected to the processing system. The processing system components can be placed under pressure by the recovery system to desorb or outgas contaminants and remove virtual leaks. The recovery system pressure can include a vacuum roughing pump, a turbomolecular pump, and/or a cryogenic pump to apply a pressure necessary to desorb or outgas the components.

Abstract: Disclosed herein are devices, methods and systems for ex-situ component recovery. The ex-situ recovery can be performed by desorbing or outgassing components of a processing system in a recovery system, rather than in the processing system itself. The recovery system can include a docking station and/or a heated vacuum chamber. The heated vacuum chamber can be used to desorb or outgas components that will be located inside the processing system, while the docking station can be used to desorb or outgas components that will be connected to the processing system. The processing system components can be placed under pressure by the recovery system to desorb or outgas contaminants and remove virtual leaks. The recovery system pressure can include a vacuum roughing pump, a turbomolecular pump, and/or a cryogenic pump to apply a pressure necessary to desorb or outgas the components.

Abstract: Disclosed herein are devices, methods and systems for implementing gettering layers. Devices including gettering layers can be implemented such that a gettering layer doped with carbon, boron, fluorine or any other appropriate impurity is formed on a semiconductor substrate, a device layer is formed on the gettering layer, and a device region is formed in the device layer having a depth that maintains a distance in the device layer between the gettering layer and the device region.

Abstract: Methods and electronic devices fabricated by those methods are disclosed where the method allows controlled movement of oxygen during fabrication of electronic and photonic devices, facilitated by a technique of oxygen updiffusion (OUD). The method includes fabrication of a compound semiconductor film, doped with either carbon or boron, over a substrate and incorporating a quantity of oxygen into either the substrate or an adjacent film layer. One or more anneal steps may be used as a partial control mechanism, along with dopant types, concentrations, and profiles, to control movement of the oxygen from the semiconductor substrate or adjacent films into the compound semiconductor film.

Abstract: A method for fabricating a heterojunction bipolar transistor (HBT) is provided. The method includes providing a substrate including a collector region; forming a compound base region over the collector region; forming a cap layer overlying the compound base region including doping the cap layer with a pre-determined percentage of at least one element associated with the compound base region; and forming an emitter region over the cap layer.

Abstract: A method and system for providing a bipolar transistor is described. The method and system include providing a compound base region including includes a compound box extension, providing an emitter region, and providing a collector region. The emitter region is coupled with the base region. The SiGe base region is coupled with the collector region and includes a SiGe box extension. The box extension resides substantially between the emitter and the heterogeneous base region.

Abstract: A method for pseudomorphic growth and integration of an in-situ doped, strain-compensated metastable compound base into an electronic device, such as, for example, a SiGe NPN HBT, by substitutional placement of strain-compensating atomic species. The invention also applies to strained layers in other electronic devices such as strained SiGe, Si in MOS applications, vertical thin film transistors (VTFT), and a variety of other electronic device types. Devices formed from compound semiconductors other than SiGe, such as, for example, GaAs, InP, and AlGaAs are also amenable to beneficial processes described herein.

Abstract: A method and system for providing a bipolar transistor is described. The method and system include providing a compound base region, providing an emitter region coupled with the compound base region, and providing a collector region coupled with the compound base region. The bipolar transistor may also include at least one other predetermined portion. The method and system also include providing at least one predetermined amount of oxygen to at least one of the compound base region, the emitter region, the collector region, and the predetermined portion of the bipolar transistor.

Abstract: A method for fabricating a heterojunction bipolar transistor (HBT) is provided. The method includes providing a substrate including a collector region; forming a compound base region over the collector region; and forming an emitter region over the compound base region including forming a first emitter layer within the emitter region and doping the first emitter layer with a pre-determined percentage of at least one element associated with the compound base region. In one implementation, an emitter region is formed including multiple emitter layers to enhance a surface recombination surface area within the emitter region.

Abstract: A method of fabricating a semiconductive film stack for use as a polysilicon germanium gate electrode to address problems associated with implant and diffusion of dopants. Achieving a sufficiently high active dopant concentration at a gate-dielectric interface while avoiding gate penetration of dopants such as boron is problematic. A higher gate implant dosage or annealing temperature is needed, and boron penetration through the thin gate oxide is inevitably enhanced. Both problems are exacerbated as the gate dielectric becomes thinner. In order to achieve a high level of active dopant concentration next to the gate dielectric without experiencing problems associated with gate depletion and penetration, a method and procedures of applying a diffusion-blocking layer is described with respect to an exemplary MOSFET application. However, a diffusion-blocking concept is also presented, which is readily amenable to a variety of semiconductor related technologies.

Abstract: A method and resulting etch-stop layer comprising a silicon-germanium layer and a dopant layer within the silicon-germanium layer. The silicon-germanium layer is comprised of less than about 70% germanium and contains one or more dopant elements selected from the group consisting of boron and carbon. The dopant layer has one or more of the dopant elements and an FWHM thickness value of less than 50 nanometers.

Abstract: A method, and a resulting device, for fabricating a heterojunction bipolar transistor (HBT). HBT devices have a high transconductance typical of bipolar devices and are additionally capable of high-power operation. To achieve the aforementioned characteristics, HBT devices are generally of the npn type, preferably with a thin, heavily doped base. The thin, heavily doped base maintains a low base-spreading resistance, leading to a high maximum oscillation frequency. In order to maintain a high doping concentration while minimizing outdiffusion of the dopant material, carbon is remotely doped into the base region. Details of the carbon dopant techniques and procedures are described with respect to fabrication of an exemplary HBT device.

Abstract: A system and apparatus for reducing contaminants of physical components (e.g., semiconductor device fabrication equipment components), featuring a manifold having a passageway in fluid communication with a plurality of inlets and for providing a purge fluid to removably connected components to undergo contaminant reduction. The inlets are coupled to a plurality of manifold valves to which components are removably connected. The manifold valves are operable to place connected components into and out of fluid communication with the inlets and the passageway. A fluid source supplies purge fluid to the manifold and a pump is connected to the manifold to remove fluid from the system. In one embodiment an oven is connected to the system for outgassing and for reduction of moisture in additional components.

Abstract: Very low moisture o-rings are prepared by placing standard o-rings under vacuum in an inert atmosphere for a period of time sufficient to achieve a desired outgassing rate. Heat is not applied. While the o-rings are under vacuum, moisture is removed from the o-rings via diffusion transport.

Abstract: A system, apparatus, and method for reducing contaminants of semiconductor device fabrication equipment components, featuring a manifold having a passageway in fluid communication with to a plurality of inlets and for providing a purge fluid to removably connected components to undergo contaminant reduction. The inlets are connected to a plurality of manifold valves to which components are removably connected. The manifold valves are operable to place connected components into and out of fluid communication with the inlets and the passageway. A fluid source supplies purge fluid to the manifold and a pump is connected to the manifold to remove fluid from the system. In one embodiment an oven is connected to the system for outgassing and for reduction of moisture in additional components.