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: 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 and apparatus for depositing single crystal, epitaxial films of silicon carbon and silicon germanium carbon on a plurality of substrates in a hot wall, isothermal UHV-CVD system is described. In particular, a multiple wafer low temperature growth technique in the range from 350° C. to 750° C. is described for incorporating carbon epitaxially in Si and SiGe films with very abrupt and well defined junctions, but without any associated oxygen background contamination. Preferably, these epitaxial SiC and SiGeC films are in-situ doped p- or n-type and with the presence of low concentration of carbon <1020 cm−3, the as-grown p- or n-type dopant profile can withstand furnace anneals to temperatures of 850° C. and rapid thermal anneal temperatures to 1000° C.

Abstract: We provide a method of doping an Si or SiGe film with carbon or boron. By reducing the silicon precursor pressure, heavily-doped films may be obtained. A single dopant source may be used. The doped Si and SiGe films are of suitable quality for use in a transistor such as an HBT.

Abstract: A method for fabricating a heterojunction bipolar transistor having collector, base and emitter regions is disclosed. In an exemplary embodiment of the invention, the method includes forming a silicon epitaxial layer upon a substrate, the silicon epitaxial layer defining the collector region. An oxide stack is formed upon the silicon epitaxial layer and a nitride layer is then formed upon the oxide stack. Next, an emitter opening is defined within the nitride layer before a base cavity is formed within the oxide stack. The base cavity extends laterally beyond the width of the emitter opening. A silicon-germanium epitaxial layer is grown within the base cavity, the silicon-germanium epitaxial layer defining the base region. Finally, a polysilicon layer is deposited upon said silicon-germanium epitaxial layer, the polysilicon layer defining the emitter region.

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 SiGe bipolar transistor containing substantially no dislocation defects present between the emitter and collector region and a method of forming the same are provided. The SiGe bipolar transistor includes a collector region of a first conductivity type; a SiGe base region formed on a portion of said collector region; and an emitter region of said first conductivity type formed over a portion of said base region, wherein said collector region and said base region include carbon continuously therein. The SiGe base region is further doped with boron.

Abstract: A SiGe bipolar transistor containing substantially no dislocation defects present between the emitter and collector region and a method of forming the same are provided. The SiGe bipolar transistor includes a collector region of a first conductivity type; a SiGe base region formed on a portion of said collector region; and an emitter region of said first conductivity type formed over a portion of said base region, wherein said collector region and said base region include carbon continuously therein. The SiGe base region is further doped with boron.

Abstract: A SiGe bipolar transistor containing substantially no dislocation defects present between the emitter and collector region and a method of forming the same are provided. The SiGe bipolar transistor includes a collector region of a first conductivity type; a SiGe base region formed on a portion of said collector region; and an emitter region of said first conductivity type formed over a portion of said base region, wherein said collector region and said base region include carbon continuously therein. The SiGe base region is further doped with boron.