Abstract: Disclosed are embodiments of a transistor, which incorporates an airgap for low base-emitter capacitance (Cbe). Each embodiment of the transistor has a monocrystalline base and, within the monocrystalline base, an intrinsic base region and an extrinsic base region positioned laterally adjacent to the intrinsic base region, wherein the intrinsic and extrinsic base regions have co-planar top surfaces. An essentially T-shaped emitter in cross-section has a lower emitter region on the intrinsic base region and an upper emitter region above the lower emitter region. Each embodiment of the transistor further has an airgap, which is positioned laterally adjacent to the lower emitter region so as to be between the extrinsic base region and the upper emitter region. Thus, the entire airgap is above the co-planar top surfaces of the intrinsic base region and the extrinsic base region. Also disclosed herein are methods of forming the transistor embodiments.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to integrated CMOS wafers and methods of manufacture. The structure includes: a chip of a first technology type comprising a trench structure on a front side; a chip of a second technology type positioned within the trench structure and embedded therein with an interlevel dielectric material; and a common wiring layer on the front side connecting to both the chip of the first technology type and the chip of the second technology type.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to a heterojunction bipolar transistor with a stress component and methods of manufacture. The heterojunction bipolar transistor includes a collector region, an emitter region and a base region. Stress material is formed within a trench of a substrate and surrounding at least the collector region and the base region.

Abstract: Device structures and fabrication methods for a device structure. One or more trench isolation regions are formed in a substrate to surround a device region. A base layer is formed on the device region. First and second emitter fingers are formed on the base layer. A portion of the device region extending from the first emitter finger to the second emitter finger is free of dielectric material.

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: 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: The present disclosure relates to semiconductor structures and, more particularly, to multiple back gate transistor structures and methods of manufacture. The structure includes: a transistor formed over a semiconductor material and an underlying substrate; and multiple isolated contact regions under a body or channel of the transistor, structured to provide a local potential to the body of the transistor at different locations.

Abstract: A method of making a semiconductor structure is provided including providing a plurality of fins on a semiconductor substrate; depositing a layer containing silicon dioxide on the plurality of fins and on a surface of the semiconductor substrate; depositing a photoresist layer on one or more but less than all of the plurality of fins; etching the layer of silicon dioxide off of one or more of the plurality of fins on which the photoresist layer had not been deposited; stripping the photoresist layer; depositing a layer of pure boron on one or more of the plurality of fins on which a photoresist had not been deposited; and depositing a silicon nitride liner step on the plurality of fins. A partial semiconductor device fabricated by said method is also provided.

Abstract: A method of making a semiconductor structure is provided including providing a plurality of fins on a semiconductor substrate; depositing a layer containing silicon dioxide on the plurality of fins and on a surface of the semiconductor substrate; depositing a photoresist layer on one or more but less than all of the plurality of fins; etching the layer of silicon dioxide off of one or more of the plurality of fins on which the photoresist layer had not been deposited; stripping the photoresist layer; depositing a layer of pure boron on one or more of the plurality of fins on which a photoresist had not been deposited; and depositing a silicon nitride liner step on the plurality of fins. A partial semiconductor device fabricated by said method is also provided.

Abstract: Device structures and fabrication methods for a device structure. One or more trench isolation regions are formed in a substrate to surround a device region. A base layer is formed on the device region. First and second emitter fingers are formed on the base layer. A portion of the device region extending from the first emitter finger to the second emitter finger is free of dielectric material.

Abstract: Device structure and fabrication methods for a bipolar junction transistor. A trench isolation region is formed that bounds an active device region along a sidewall. A dielectric region is formed that extends laterally from the sidewall of the active device region into the active device region. The dielectric region is located beneath a top surface of the active device region such that a section of the active device region is located between the top surface and the dielectric region.

Abstract: A method of making a semiconductor structure is provided including providing a plurality of fins on a semiconductor substrate; depositing a layer containing silicon dioxide on the plurality of fins and on a surface of the semiconductor substrate; depositing a photoresist layer on one or more but less than all of the plurality of fins; etching the layer of silicon dioxide off of one or more of the plurality of fins on which the photoresist layer had not been deposited; stripping the photoresist layer; depositing a layer of pure boron on one or more of the plurality of fins on which a photoresist had not been deposited; and depositing a silicon nitride liner step on the plurality of fins. A partial semiconductor device fabricated by said method is also provided.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to integrated CMOS wafers and methods of manufacture. The structure includes: a chip of a first technology type comprising a trench structure on a front side; a chip of a second technology type positioned within the trench structure and embedded therein with an interlevel dielectric material; and a common wiring layer on the front side connecting to both the chip of the first technology type and the chip of the second technology type.

Abstract: Device structures, fabrication methods, and design structures for a bipolar junction transistor. A trench isolation region is formed in a substrate. The trench isolation region is coextensive with a collector in the substrate. A base layer is formed on the collector and on a first portion of the trench isolation region. A dielectric layer is formed on the base layer and on a second portion of the trench isolation region peripheral to the base layer. After the dielectric layer is formed, the trench isolation region is at least partially removed to define an air gap beneath the dielectric layer and the base layer.

Abstract: Device structure and fabrication methods for a bipolar junction transistor. One or more trench isolation regions are formed in a substrate to define a device region having a first width. A protect layer is formed on a top surface of the one or more trench isolation regions and a top surface of the device region. An opening is formed in the protect layer. The opening is coincides with the top surface of the first device region and has a second width that is less than or equal to the first width of the first device region. A base layer is formed that has a first section on the device region inside the first opening and a second section on the protect layer.

Abstract: Device structure and fabrication methods for a bipolar junction transistor. One or more trench isolation regions are formed in a substrate to define a device region having a first width. A protect layer is formed on a top surface of the one or more trench isolation regions and a top surface of the device region. An opening is formed in the protect layer. The opening is coincides with the top surface of the first device region and has a second width that is less than or equal to the first width of the first device region. A base layer is formed that has a first section on the device region inside the first opening and a second section on the protect layer.

Abstract: Device structures for a bipolar junction transistor. A layer is formed on a top surface of a substrate. A trench is formed in the layer and has a plurality of sidewalls with a width between an opposite pair of the sidewalls that varies with increasing distance from the top surface of the substrate. A collector pedestal of the bipolar junction transistor is formed in the trench.

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: 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: Device structure and fabrication methods for a bipolar junction transistor. A trench isolation region is formed that bounds an active device region along a sidewall. A dielectric region is formed that extends laterally from the sidewall of the active device region into the active device region. The dielectric region is located beneath a top surface of the active device region such that a section of the active device region is located between the top surface and the dielectric region.