Abstract: Multi-die composite structures including a multi-layered inorganic dielectric gap fill material within a space between adjacent IC dies. A first layer of fill material with an inorganic composition may be deposited over IC dies with a high-rate deposition process, for example to at least partially fill a space between the IC dies. The first layer of fill material may then be partially removed to modify a sidewall slope of the first layer or otherwise reduce an aspect ratio of the space between the IC dies. Another layer of fill material may be deposited over the lower layer of fill material, for example with the same high-rate deposition process. This dep-etch-dep cycle may be repeated any number of times to backfill spaces between IC dies. The multi-layer fill material may then be globally planarized and the IC die package completed and/or assembled into a next-level of integration.

Abstract: According to a semiconductor device herein, the device includes a substrate. An active device is formed in the substrate. The active device includes a collector region, a base region formed on the collector region, and an emitter region formed on the base region. An isolation structure is formed in the substrate around the active device. A trench filled with a compressive material is formed in the substrate and positioned laterally adjacent to the emitter region and base region. The trench extends at least partially into the collector region.

Abstract: A device structure for a bipolar junction transistor includes a base layer made of a semiconductor material. An emitter is disposed on a first portion of the base layer. A dopant-containing layer is disposed on a second portion of the base layer. A hardmask is disposed on the base layer. The hardmask includes a window aligned with the second portion of the base layer. Deposits of the dopant-containing layer are limited to exposed surfaces of: the first portion that is disposed on a top surface of the base layer inside of the window.

Abstract: According to a semiconductor device herein, the device includes a substrate. An active device is formed in the substrate. The active device includes a collector region, a base region formed on the collector region, and an emitter region formed on the base region. An isolation structure is formed in the substrate around the active device. A trench filled with a compressive material is formed in the substrate and positioned laterally adjacent to the emitter region and base region. The trench extends at least partially into the collector region.

Abstract: According to a semiconductor device herein, the device includes a substrate. An active device is formed in the substrate. The active device includes a collector region, a base region formed on the collector region, and an emitter region formed on the base region. An isolation structure is formed in the substrate around the active device. A trench filled with a compressive material is formed in the substrate and positioned laterally adjacent to the emitter region and base region. The trench extends at least partially into the base region.

Abstract: A method includes forming a base layer on a top surface of a substrate. A dielectric layer is formed on exposed surfaces of the base layer. A hardmask layer is formed on the base layer and the dielectric layer. A pattern is formed from the hardmask with a first opening and a second opening. Portions of a dielectric layer are removed from the top surface of the base layer at positions consistent with the pattern of the first opening and the second opening to form exposed surfaces defined as a first window and a second window in the dielectric layer. Deposits of a dopant-containing layer are limited on the exposed surfaces of: a first portion on the top surface of the base layer inside of the first window, and a second portion on the top surface of the base layer inside of the second window.

Abstract: A method includes forming a base layer on a top surface of a substrate. A dielectric layer is formed on exposed surfaces of the base layer. A hardmask layer is formed on the base layer and the dielectric layer. A pattern is formed from the hardmask with a first opening and a second opening. Portions of a dielectric layer are removed from the top surface of the base layer at positions consistent with the pattern of the first opening and the second opening to form exposed surfaces defined as a first window and a second window in the dielectric layer. Deposits of a dopant-containing layer are limited on the exposed surfaces of: a first portion on the top surface of the base layer inside of the first window, and a second portion on the top surface of the base layer inside of the second window.

Abstract: A device structure for a bipolar junction transistor includes a base layer made of a semiconductor material. An emitter is disposed on a first portion of the base layer. A dopant-containing layer is disposed on a second portion of the base layer. A hardmask is disposed on the base layer. The hardmask includes a window aligned with the second portion of the base layer. Deposits of the dopant-containing layer are limited to exposed surfaces of: the first portion that is disposed on a top surface of the base layer inside of the window.

Abstract: Methods for forming a device structure and device structures using a silicon-on-insulator substrate that includes a high-resistance handle wafer. A doped region is formed in the high-resistance handle wafer. A first trench is formed that extends through a device layer and a buried insulator layer of the silicon-on-insulator substrate to the high-resistance handle wafer. The doped region includes lateral extension of the doped region extending laterally of the first trench. A semiconductor layer is epitaxially grown within the first trench, and a device structure is formed using at least a portion of the semiconductor layer. A second trench is formed that extends through the device layer and the buried insulator layer to the lateral extension of the doped region, and a conductive plug is formed in the second trench. The doped region and the plug comprise a body contact.

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 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 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: 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: 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: The present disclosure relates to semiconductor structures and, more particularly, to transistors with improved channel mobility and methods of manufacture. A structure includes: a curved beam structure formed from at least one stressed material; a cavity below the curved beam structure; and at least one semiconductor device on a top portion or a bottom portion of the curved beam structure whose carrier mobility is increased or decreased by a curvature of the curved beam structure.

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: According to a semiconductor device herein, the device includes a substrate. An active device is formed in the substrate. The active device includes a collector region, a base region formed on the collector region, and an emitter region formed on the base region. An isolation structure is formed in the substrate around the active device. A trench filled with a compressive material is formed in the substrate and positioned laterally adjacent to the emitter region and base region. The trench extends at least partially into the base region.

Abstract: Device structures and fabrication methods for a bipolar junction transistor. The device structure includes an intrinsic base, an emitter having a vertical arrangement relative to the intrinsic base, and a collector having a lateral arrangement relative to the intrinsic base. The device structure may be fabricated by forming the intrinsic base and the collector in a semiconductor layer, and epitaxially growing the emitter on the intrinsic base and with a vertical arrangement relative to the intrinsic base. The collector and the intrinsic base have a lateral arrangement within the semiconductor layer.

Abstract: Device structures and fabrication methods for a bipolar junction transistor. The device structure includes an intrinsic base, an emitter having a vertical arrangement relative to the intrinsic base, and a collector having a lateral arrangement relative to the intrinsic base. The device structure may be fabricated by forming the intrinsic base and the collector in a semiconductor layer, and epitaxially growing the emitter on the intrinsic base and with a vertical arrangement relative to the intrinsic base. The collector and the intrinsic base have a lateral arrangement within the semiconductor layer.

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.