Abstract: Fabrication methods and device structures for a heterojunction bipolar transistor. A trench isolation region is formed that surrounds an active region of semiconductor material, a collector is formed in the active region, and a base layer is deposited that includes a first section over the trench isolation region, a second section over the active region, and a third section over the active region that connects the first section and the second section. An emitter is arranged over the second section of the base layer, and an extrinsic base layer is arranged over the first section of the base layer and the third section of the base layer. The extrinsic base layer includes a first section containing polycrystalline semiconductor material and a second section containing single-crystal semiconductor material. The first and second sections of the extrinsic base layer intersect along an interface that extends over the trench isolation region.

Abstract: Fabrication methods and device structures for heterojunction bipolar transistors. A first emitter of a first heterojunction bipolar transistor and a second collector of a second heterojunction bipolar transistor are formed in a device layer of a silicon-on-insulator substrate. A first base layer of a first heterojunction bipolar transistor is epitaxially grown on the device layer with an intrinsic base portion arranged on the first emitter. A first collector of the first heterojunction bipolar transistor is epitaxially grown on the intrinsic base portion of the first base layer. A second base layer of the second heterojunction bipolar transistor is epitaxially grown on the device layer with an intrinsic base portion arranged on the second collector. A second emitter of the second heterojunction bipolar transistor is epitaxially grown on the intrinsic base portion of the second base layer. A connection is formed between the first emitter and the second collector.

Abstract: Device structure and fabrication methods for a bipolar junction transistor. A base layer is formed and an emitter is formed on a first portion of the base layer. A dopant-containing layer is deposited on a second portion of the base layer. Dopant is transferred from the dopant-containing layer into the second portion of the base layer to define an extrinsic base of the device structure.

Abstract: Fabrication methods and device structures for heterojunction bipolar transistors. A first emitter of a first heterojunction bipolar transistor and a second collector of a second heterojunction bipolar transistor are formed in a device layer of a silicon-on-insulator substrate. A first base layer of a first heterojunction bipolar transistor is epitaxially grown on the device layer with an intrinsic base portion arranged on the first emitter. A first collector of the first heterojunction bipolar transistor is epitaxially grown on the intrinsic base portion of the first base layer. A second base layer of the second heterojunction bipolar transistor is epitaxially grown on the device layer with an intrinsic base portion arranged on the second collector. A second emitter of the second heterojunction bipolar transistor is epitaxially grown on the intrinsic base portion of the second base layer. A connection is formed between the first emitter and the second collector.

Abstract: Device structures for a bipolar junction transistor and methods for fabricating a device structure using a substrate. One or more primary trench isolation regions are formed that surround an active device region of the substrate and a collector contact region of the substrate. A base layer is formed on the active device region and the collector contact region, and the active device region includes a collector. Each primary trench isolation region extends vertically to a first depth into the substrate. A trench is formed laterally located between the base layer and the collector contact region and that extends vertically through the base layer and into the substrate to a second depth that is less than the first depth. A dielectric is formed in the trench to form a secondary trench isolation region. An emitter is formed on the base layer.

Abstract: Fabrication methods and device structures for heterojunction bipolar transistors. A first emitter of a first heterojunction bipolar transistor and a second collector of a second heterojunction bipolar transistor are formed in a device layer of a silicon-on-insulator substrate. A first base layer of a first heterojunction bipolar transistor is epitaxially grown on the device layer with an intrinsic base portion arranged on the first emitter. A first collector of the first heterojunction bipolar transistor is epitaxially grown on the intrinsic base portion of the first base layer. A second base layer of the second heterojunction bipolar transistor is epitaxially grown on the device layer with an intrinsic base portion arranged on the second collector. A second emitter of the second heterojunction bipolar transistor is epitaxially grown on the intrinsic base portion of the second base layer. A connection is formed between the first emitter and the second collector.

Abstract: Device structures for a bipolar junction transistor and methods for fabricating a device structure using a substrate. One or more primary trench isolation regions are formed that surround an active device region of the substrate and a collector contact region of the substrate. A base layer is formed on the active device region and the collector contact region, and the active device region includes a collector. Each primary trench isolation region extends vertically to a first depth into the substrate. A trench is formed laterally located between the base layer and the collector contact region and that extends vertically through the base layer and into the substrate to a second depth that is less than the first depth. A dielectric is formed in the trench to form a secondary trench isolation region. An emitter is formed on the base layer.

Abstract: Device structures and fabrication methods for heterojunction bipolar transistors. Trench isolation regions are arranged to surround a plurality of active regions, and a collector is located in each of the active regions. A base layer includes a plurality of first sections that are respectively arranged over the active regions and a plurality of second sections that are respectively arranged over the trench isolation regions. The first sections of the base layer contain single-crystal semiconductor material, and the second sections of the base layer contain polycrystalline semiconductor material. The second sections of the base layer are spaced in a vertical direction from the trench isolation regions to define a plurality of cavities. A plurality of emitter fingers are respectively arranged on the first sections of the base layer.

Abstract: A field effect transistor (FET) with an underlying airgap and methods of manufacture are disclosed. The method includes forming an amorphous layer at a predetermined depth of a substrate. The method further includes forming an airgap in the substrate under the amorphous layer. The method further includes forming a completely isolated transistor in an active region of the substrate, above the amorphous layer and the airgap.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to a switch with local silicon on insulator (SOI) and deep trench isolation structures and methods of manufacture. The structure a structure comprises an air gap located under a device region and bounded by an upper etch stop layer and deep trench isolation structures.

Abstract: Device structures and fabrication methods for heterojunction bipolar transistors. A trench isolation region surrounds an active region that includes a collector, and a base layer includes a first section composed of a single-crystal semiconductor material that is arranged over the active region and a second section composed of polycrystalline semiconductor material that is arranged over the trench isolation region. A first semiconductor layer of the second section of the base layer is removed selective to a second semiconductor layer of the second section of the base layer to define a gap arranged in a vertical direction between the second semiconductor layer of the second section of the base layer and the trench isolation region. An emitter is formed on the first section of the base layer.

Abstract: Various particular embodiments include an integrated circuit (IC) structure having: a stack region; and a silicon substrate underlying and contacting the stack region, the silicon substrate including: a silicon region including a doped subcollector region; a set of isolation regions overlying the silicon region; a base region between the set of isolation regions and below the stack region, the base region including an intrinsic base contacting the stack region, an extrinsic base contacting the intrinsic base and the stack region, and an amorphized extrinsic base contact region contacting the extrinsic base; a collector region between the set of isolation regions; an undercut collector-base region between the set of isolation regions and below the base region; and a collector contact region contacting the collector region under the intrinsic base and the collector-base region via the doped subcollector region.

Abstract: A field effect transistor (FET) with an underlying airgap and methods of manufacture are disclosed. The method includes forming an amorphous layer at a predetermined depth of a substrate. The method further includes forming an airgap in the substrate under the amorphous layer. The method further includes forming a completely isolated transistor in an active region of the substrate, above the amorphous layer and the airgap.

Abstract: Fabrication methods and device structures for heterojunction bipolar transistors. A first emitter of a first heterojunction bipolar transistor and a second collector of a second heterojunction bipolar transistor are formed in a device layer of a silicon-on-insulator substrate. A first base layer of a first heterojunction bipolar transistor is epitaxially grown on the device layer with an intrinsic base portion arranged on the first emitter. A first collector of the first heterojunction bipolar transistor is epitaxially grown on the intrinsic base portion of the first base layer. A second base layer of the second heterojunction bipolar transistor is epitaxially grown on the device layer with an intrinsic base portion arranged on the second collector. A second emitter of the second heterojunction bipolar transistor is epitaxially grown on the intrinsic base portion of the second base layer. A connection is formed between the first emitter and the second collector.

Abstract: Device structure and fabrication methods for a bipolar junction transistor. An emitter layer is formed on a base layer and etched to form an emitter of the device structure. The emitter layer has a concentration of an element that varies as a function of the thickness of the emitter layer. The etch rate of the emitter layer varies as a function of the concentration of the element such that the emitter has a variable width over the thickness of the emitter layer.

Abstract: Disclosed are structures and methods of forming the structures so as to have a photodetector isolated from a substrate by stacked trench isolation regions. In one structure, a first trench isolation region is in and at the top surface of a substrate and a second trench isolation region is in the substrate below the first. A photodetector is on the substrate aligned above the first and second trench isolation regions. In another structure, a semiconductor layer is on an insulator layer and laterally surrounded by a first trench isolation region. A second trench isolation region is in and at the top surface of a substrate below the insulator layer and first trench isolation region. A photodetector is on the semiconductor layer and extends laterally onto the first trench isolation region. The stacked trench isolation regions provide sufficient isolation below the photodetector to allow for direct coupling with an off-chip optical fiber.

Abstract: The present disclosure generally relates to semiconductor structures and, more particularly, to heterojunction bipolar transistor device integration schemes on a same wafer and methods of manufacture. The structure includes: a power amplifier (PA) device comprising a base, a collector and an emitter on a wafer; and a low-noise amplifier (LNA) device comprising a base, a collector and an emitter on the wafer, with the emitter having a same crystalline structure as the base.

Abstract: A tunable breakdown voltage RF MESFET and/or MOSFET and methods of manufacture are disclosed. The method includes forming a first line and a second line on an underlying gate dielectric material. The second line has a width tuned to a breakdown voltage. The method further includes forming sidewall spacers on sidewalls of the first and second line such that the space between first and second line is pinched-off by the dielectric spacers. The method further includes forming source and drain regions adjacent outer edges of the first line and the second line, and removing at least the second line to form an opening between the sidewall spacers of the second line and to expose the underlying gate dielectric material. The method further includes depositing a layer of material on the underlying gate dielectric material within the opening, and forming contacts to a gate structure and the source and drain regions.

Abstract: Fabrication methods and device structures for bipolar junction transistors and heterojunction bipolar transistors. A first dielectric layer is formed and a second dielectric layer is formed on the first dielectric layer. An opening is etched extending vertically through the first dielectric layer and the second dielectric layer. A collector is formed inside the opening. An intrinsic base, which is also formed inside the opening, has a vertical arrangement relative to the collector.

Abstract: A tunable breakdown voltage RF MESFET and/or MOSFET and methods of manufacture are disclosed. The method includes forming a first line and a second line on an underlying gate dielectric material. The second line has a width tuned to a breakdown voltage. The method further includes forming sidewall spacers on sidewalls of the first and second line such that the space between first and second line is pinched-off by the dielectric spacers. The method further includes forming source and drain regions adjacent outer edges of the first line and the second line, and removing at least the second line to form an opening between the sidewall spacers of the second line and to expose the underlying gate dielectric material. The method further includes depositing a layer of material on the underlying gate dielectric material within the opening, and forming contacts to a gate structure and the source and drain regions.