Abstract: A process of forming a nitride film on a semiconductor substrate including exposing a surface of the substrate to a rapid thermal process to form the nitride film.

Abstract: A method of fabricating a SiGe heterojunction bipolar transistor (HBT) is provided which results in a SiGe HBT that has a controllable current gain and improved breakdown voltage. The SiGe HBT having these characteristics is fabricated by forming an in-situ P-doped emitter layer atop a patterned SiGe base structure. The in-situ P-doped emitter layer is a bilayer of in-situ P-doped a:Si and in-situ P-doped polysilicon. The SiGe HBT structure including the above mentioned bilayer emitter is also described herein.

Abstract: A method of fabricating a SiGe heterojunction bipolar transistor (HBT) is provided which results in a SiGe HBT that has a controllable current gain and improved breakdown voltage. The SiGe HBT having these characteristics is fabricated by forming an in-situ P-doped emitter layer atop a patterned SiGe base structure. The in-situ P-doped emitter layer is a bilayer of in-situ P-doped a:Si and in-situ P-doped polysilicon. The SiGe HBT structure including the above mentioned bilayer emitter is also described herein.

Abstract: A raised extrinsic base, silicon germanium (SiGe) heterojunction bipolar transistor (HBT), and a method of making the same is disclosed herein. The heterojunction bipolar transistor includes a substrate, a silicon germanium layer formed on the substrate, a collector layer formed on the substrate, a raised extrinsic base layer formed on the silicon germanium layer, and an emitter layer formed on the silicon germanium layer. The silicon germanium layer forms a heterojunction between the emitter layer and the raised extrinsic base layer. The bipolar transistor further includes a base electrode formed on a portion of the raised extrinsic base layer, a collector electrode formed on a portion of the collector layer, and an emitter electrode formed on a portion of the emitter layer. Thus, the heterojunction bipolar transistor includes a self-aligned raised extrinsic base, a minimal junction depth, and minimal interstitial defects influencing the base width, all being formed with minimal thermal processing.

Abstract: A method for forming a heterojunction bipolar transistor includes forming two sets of spacers on the sides of an emitter pedestal. After the first set of spacers is formed, first extrinsic base regions are implanted on either side of an intrinsic base. The second set of spacers is formed on the first set of spacers. Second extrinsic base regions are then implanted on respective sides of the intrinsic base. By using two sets of spacers, the first and second extrinsic base regions have different widths. This advantageously brings the combined extrinsic base structure closer to the emitter of the transistor but not closer to the collector. As a result, the base parasitic resistance is reduced along with collector-to-extrinsic base parasitic capacitance. The performance of the transistor is further enhanced as a result of the extrinsic base regions being self-aligned to the emitter and collector.

Abstract: The present invention provides a unique device structure and method that provides increased transistor performance in integrated bipolar circuit devices. The preferred embodiment of the present invention provides improved high speed performance with a stepped collector dopant profile that reduces emitter-collector transit time and parasitic resistance with minimal increase in parasitic capacitances. The preferred stepped collector dopant profile includes a shallow implant and a deeper implant. The shallow implant reduces the base-collector space-charge region width, reduce resistance, and tailors the collector-base breakdown characteristics. The deeper implant links the buried collector to the subcollector and provides a low resistance path to the subcollector. The stepped collector dopant profile has minimal impact on the collector-base capacitance outside the intrinsic region of the device since the higher dopant is compensated by, or buried in, the extrinsic base dopants outside the intrinsic region.

Abstract: A method for making a non-self-aligned, heterojunction bipolar transistor includes forming extrinsic base regions with a PFET source/drain implant aligned with the polysilicon in an emitter stack but which are not directly aligned with an emitter opening defined in that stack. This is achieved by making the emitter pedestal wider than the emitter opening. This advantageously removes the dependency of alignment between the extrinsic base regions and the emitter opening, thereby resulting in fewer process steps, reduced thermal cycles, and improved speed.

Abstract: A method for forming a heterojunction bipolar transistor includes forming two sets of spacers on the sides of an emitter pedestal. After the first set of spacers is formed, first extrinsic base regions are implanted on either side of an intrinsic base. The second set of spacers is formed on the first set of spacers. Second extrinsic base regions are then implanted on respective sides of the intrinsic base. By using two sets of spacers, the first and second extrinsic base regions have different widths. This advantageously brings the combined extrinsic base structure closer to the emitter of the transistor but not closer to the collector. As a result, the base parasitic resistance is reduced along with collector-to-extrinsic base parasitic capacitance. The performance of the transistor is further enhanced as a result of the extrinsic base regions being self-aligned to the emitter and collector.

Abstract: The present invention provides a unique device structure and method that provides increased transistor performance in integrated bipolar circuit devices. The preferred embodiment of the present invention provides improved high speed performance with a stepped collector dopant profile that reduces emitter-collector transit time and parasitic resistance with minimal increase in parasitic capacitances. The preferred stepped collector dopant profile includes a shallow implant and a deeper implant. The shallow implant reduces the base-collector space-charge region width, reduce resistance, and tailors the collector-base breakdown characteristics. The deeper implant links the buried collector to the subcollector and provides a low resistance path to the subcollector. The stepped collector dopant profile has minimal impact on the collector-base capacitance outside the intrinsic region of the device since the higher dopant is compensated by, or buried in, the extrinsic base dopants outside the intrinsic region.

Abstract: In supersonic molecular beam etching, the reactivity of the etchant gas and substrate surface is improved by creating etchant gas molecules with high internal energies through chemical reactions of precursor molecules, forming clusters of etchant gas molecules in a reaction chamber, expanding the etchant gas molecules and clusters of etchant gas molecules through a nozzle into a vacuum, and directing the molecules and clusters of molecules onto a substrate. Translational energy of the molecules and clusters of molecules can be improved by seeding with inert gas molecules. The process provides improved controllability, surface purity, etch selectivity and anisotropy. Etchant molecules may also be expanded directly (without reaction in a chamber) to produce clusters whose translational energy can be increased through expansion with a seeding gas.

Abstract: A polyemitter structure having a thin interfacial layer deposited between the polysilicon emitter contact and the crystalline silicon emitter, as opposed to a regrown SiO.sub.x layer, has improved reproducibility and performance characteristics. A n-doped hydrogenated microcrystalline silicon film can be used as the deposited interfacial film between a crystalline silicon emitter and a polycrystalline silicon contact.

Abstract: In supersonic molecular beam etching, the reactivity of the etchant gas and substrate surface is improved by creating etchant gas molecules with high internal energies through chemical reactions of precursor molecules, forming clusters of etchant gas molecules in a reaction chamber, expanding the etchant gas molecules and clusters of etchant gas molecules through a nozzle into a vacuum, and directing the molecules and clusters of molecules onto a substrate. Translational energy of the molecules and clusters of molecules can be improved by seeding with inert gas molecules. The process provides improved controllability, surface purity, etch selectivity and anisotropy. Etchant molecules may also be expanded directly (without reaction in a chamber) to produce clusters whose translational energy can be increased through expansion with a seeding gas.

Abstract: New device and method are described for accurate etching and removal of thin layer by controlling the surface residence time, thickness and composition of reactant containing film. Etching of silicon dioxide at low pressure using a quartz crystal microbalance is illustrated. Usefulness of the invention in the manufacture of microelectronic devices is shown.