Abstract: Device structures, fabrication methods, operating methods, and design structures for a silicon controlled rectifier. The method includes applying a mechanical stress to a region of a silicon controlled rectifier (SCR) at a level sufficient to modulate a trigger current of the SCR. The device and design structures include a SCR with an anode, a cathode, a first region, and a second region of opposite conductivity type to the first region. The first and second regions of the SCR are disposed in a current-carrying path between the anode and cathode of the SCR. A layer is positioned on a top surface of a semiconductor substrate relative to the first region and configured to cause a mechanical stress in the first region of the SCR at a level sufficient to modulate a trigger current of the SCR.

Abstract: An integrated circuit (IC) chip is provided comprising at least one trench including a stress-inducing material which imparts a stress on a channel region of a device, such as a junction gate field-effect transistor (JFET) or a metal-oxide-semiconductor field-effect transistor (MOSFET). A related method is also disclosed.

Abstract: Disclosed are embodiments of an improved transistor structure (e.g., a bipolar transistor (BT) structure or heterojunction bipolar transistor (HBT) structure) and a method of forming the transistor structure. The structure embodiments can incorporate a dielectric layer sandwiched between an intrinsic base layer and a raised extrinsic base layer to reduce collector-base capacitance Ccb, a sidewall-defined conductive strap for an intrinsic base layer to extrinsic base layer link-up region to reduce base resistance Rb and a dielectric spacer between the extrinsic base layer and an emitter layer to reduce base-emitter Cbe capacitance. The method embodiments allow for self-aligning of the emitter to base regions and further allow the geometries of different features (e.g., the thickness of the dielectric layer, the width of the conductive strap, the width of the dielectric spacer and the width of the emitter layer) to be selectively adjusted in order to optimize transistor performance.

Abstract: An integrated circuit (IC) chip is provided comprising at least one trench including a stress-inducing material which imparts a stress on a channel region of a device, such as a junction gate field-effect transistor (JFET) or a metal-oxide-semiconductor field-effect transistor (MOSFET). A related method is also disclosed.

Abstract: Disclosed are embodiments of a hetero-junction bipolar transistor (HBT) structure and method of forming the structure that provides substantially lower collector-to-base parasitic capacitance and collector resistance, while also lowering or maintaining base-to-emitter capacitance, emitter resistance and base resistance in order to achieve frequency capabilities in the THz range. The HBT is a collector-up HBT in which a dielectric layer and optional sidewall spacers separate the raised extrinsic base and the collector so as to reduce collector-to-base capacitance. A lower portion of the collector is single crystalline semiconductor so as to reduce collector resistance. The raised extrinsic base and the intrinsic base are stacked single crystalline epitaxial layers, where link-up is automatic and self-aligned, so as to reduce base resistance. The emitter is a heavily doped region below the top surface of a single crystalline semiconductor substrate so as to reduce emitter resistance.

Abstract: An improved bipolar transistor with dual shallow trench isolation for reducing the parasitic component of the base to collector capacitance Ccb and base resistance Rb is provided. The structure includes a semiconductor substrate having at least a pair of neighboring first shallow trench isolation (STI) regions disposed therein. The pair of neighboring first STI regions defines an active area in the substrate. The structure also includes a collector disposed in the in the active area of the semiconductor substrate, a base layer disposed atop a surface of the semiconductor substrate in the active area, and a raised extrinsic base disposed on the base layer. In accordance with the present, the raised extrinsic base has an opening to a portion of the base layer. An emitter is located in the opening and extending on a portion of the patterned raised extrinsic base; the emitter is spaced apart and isolated from the raised extrinsic base.

Abstract: Device structures for a high voltage junction field effect transistor and design structures for a high voltage integrated circuit. The device structure is manufactured using a hybrid orientation technology wafer with a first semiconductor layer with a first crystalline orientation, a second semiconductor layer with a second crystalline orientation, and an insulating layer between the first and second semiconductor layers. The device structure includes an epitaxial semiconductor region having the second crystalline orientation and first and second p-n junctions in the epitaxial semiconductor region. The epitaxial semiconductor region extends from the second semiconductor layer through the insulating layer and the first semiconductor layer toward a top surface of the first semiconductor layer. The first and second p-n junctions are arranged in depth within the epitaxial semiconductor region between the second semiconductor layer and the top surface of the first semiconductor layer.

Abstract: Methods for fabricating a heterojunction bipolar transistor having a raised extrinsic base is provided in which the base resistance is reduced by forming a silicide atop the raised extrinsic base that extends to the emitter region in a self-aligned manner. The silicide formation is incorporated into a BiCMOS process flow after the raised extrinsic base has been formed. The present invention also provides a heterojunction bipolar transistor having a raised extrinsic base and a silicide located atop the raised extrinsic base. The silicide atop the raised extrinsic base extends to the emitter in a self-aligned manner. The emitter is separated from the silicide by a spacer.

Abstract: Methods for manufacturing a high voltage junction field effect transistor. The method includes forming an opening extending from a top surface of a device layer of a hybrid orientation technology (HOT) wafer through the device layer and an insulating layer to expose a portion of a bulk layer, and filling the opening with epitaxial semiconductor material having the crystalline orientation of the bulk layer. The method further includes forming first and second p-n junctions in the epitaxial semiconductor material that are arranged in depth within the epitaxial semiconductor material between the second semiconductor layer and the top surface of the first semiconductor layer.

Abstract: Device structures for a high voltage junction field effect transistor and design structures for a high voltage integrated circuit. The device structure is manufactured using a hybrid orientation technology wafer with a first semiconductor layer with a first crystalline orientation, a second semiconductor layer with a second crystalline orientation, and an insulating layer between the first and second semiconductor layers. The device structure includes an epitaxial semiconductor region having the second crystalline orientation and first and second p-n junctions in the epitaxial semiconductor region. The epitaxial semiconductor region extends from the second semiconductor layer through the insulating layer and the first semiconductor layer toward a top surface of the first semiconductor layer. The first and second p-n junctions are arranged in depth within the epitaxial semiconductor region between the second semiconductor layer and the top surface of the first semiconductor layer.

Abstract: Disclosed are embodiments of a hetero-junction bipolar transistor (HBT) structure and method of forming the structure that provides substantially lower collector-to-base parasitic capacitance and collector resistance, while also lowering or maintaining base-to-emitter capacitance, emitter resistance and base resistance in order to achieve frequency capabilities in the THz range. The HBT is a collector-up HBT in which a dielectric layer and optional sidewall spacers separate the raised extrinsic base and the collector so as to reduce collector-to-base capacitance. A lower portion of the collector is single crystalline semiconductor so as to reduce collector resistance. The raised extrinsic base and the intrinsic base are stacked single crystalline epitaxial layers, where link-up is automatic and self-aligned, so as to reduce base resistance. The emitter is a heavily doped region below the top surface of a single crystalline semiconductor substrate so as to reduce emitter resistance.

Abstract: Methods for fabricating a heterojunction bipolar transistor having a raised extrinsic base is provided in which the base resistance is reduced by forming a silicide atop the raised extrinsic base that extends to the emitter region in a self-aligned manner. The silicide formation is incorporated into a BiCMOS process flow after the raised extrinsic base has been formed. The present invention also provides a heterojunction bipolar transistor having a raised extrinsic base and a silicide located atop the raised extrinsic base. The silicide atop the raised extrinsic base extends to the emitter in a self-aligned manner. The emitter is separated from the silicide by a spacer.

Abstract: A structure and method where C is incorporated into the collector region of a heterojunction bipolar device by a method which does not include C ion implantation are provided. In the present invention, C is incorporated into the collector by epitaxy in a perimeter trench etched into the collector region to better control the carbon profile and location. The trench is formed by etching the collector region using the trench isolation regions and a patterned layer over the center part of the collector as masks. Then, Si:C is grown using selective epitaxy inside the trench to form a Si:C region with sharp and well-defined edges. The depth, width and C content can be optimized to control and tailor the collector implant diffusion and to reduce the perimeter component of parasitic CCB.

Abstract: Bipolar transistor device structures that improve bipolar device reliability with little or no negative impact on device performance. In one embodiment, the bipolar device has a collector of first conductivity type material formed in a substrate, a base of a second conductivity type material including an extrinsic base layer and an intrinsic base layer, a raised emitter of a first conductivity type semiconductor material formed on the intrinsic base layer, and, a dielectric material layer separating the intrinsic base region and the raised emitter region, and, a thin “shunt” layer of dopant of second conductivity type material added to the region below the emitter dielectric layer. In a second embodiment, a selectively implanted collector (pedestal implant) is added to the vertical bipolar transistor device to enable a reduction in overall subcollector doping level to improve reliability without sacrificing device performance.

Abstract: Methods for fabricating a heterojunction bipolar transistor having a raised extrinsic base is provided in which the base resistance is reduced by forming a silicide atop the raised extrinsic base that extends to the emitter region in a self-aligned manner. The silicide formation is incorporated into a BiCMOS process flow after the raised extrinsic base has been formed. The present invention also provides a heterojunction bipolar transistor having a raised extrinsic base and a silicide located atop the raised extrinsic base. The silicide atop the raised extrinsic base extends to the emitter in a self-aligned manner. The emitter is separated from the silicide by a spacer.

Abstract: An improved bipolar transistor with dual shallow trench isolation for reducing the parasitic component of the base to collector capacitance Ccb and base resistance Rb is provided. The structure includes a semiconductor substrate having at least a pair of neighboring first shallow trench isolation (STI) regions disposed therein. The pair of neighboring first STI regions defines an active area in the substrate. The structure also includes a collector disposed in the in the active area of the semiconductor substrate, a base layer disposed atop a surface of the semiconductor substrate in the active area, and a raised extrinsic base disposed on the base layer. In accordance with the present, the raised extrinsic base has an opening to a portion of the base layer. An emitter is located in the opening and extending on a portion of the patterned raised extrinsic base; the emitter is spaced apart and isolated from the raised extrinsic base.

Abstract: A self-aligned oxide mask is formed utilizing differential oxidation rates of different materials. The self-aligned oxide mask is formed on a CVD grown base NPN base layer which compromises single crystal Si (or Si/SiGe) at active area and polycrystal Si (or Si/SiGe) on the field. The self-aligned mask is fabricated by taking advantage of the fact that poly Si (or Si/SiGe) oxidizes faster than single crystal Si (or Si/SiGe). An oxide film is formed over both the poly Si (or Si/siGe) and the single crystal Si (or Si/siGe) by using an thermal oxidation process to form a thick oxidation layer over the poly Si (or Si/siGe) and a thin oxidation layer over the single crystal Si (or Si/siGe), followed by a controlled oxide etch to remove the thin oxidation layer over the single crystal Si (or Si/siGe) while leaving the self-aligned oxide mask layer over the poly Si (or Si/siGe). A raised extrinsic base is then formed following the self-aligned mask formation.

Abstract: A bipolar transistor with raised extrinsic base and selectable self-alignment between the extrinsic base and the emitter is disclosed. The fabrication method may include the formation of a predefined thickness of a first extrinsic base layer of polysilicon or silicon on an intrinsic base. A dielectric landing pad is then formed by lithography on the first extrinsic base layer. Next, a second extrinsic base layer of polysilicon or silicon is formed on top of the dielectric landing pad to finalize the raised extrinsic base total thickness. An emitter opening is formed using lithography and RIE, where the second extrinsic base layer is etched stopping on the dielectric landing pad. The degree of self-alignment between the emitter and the raised extrinsic base is achieved by selecting the first extrinsic base layer thickness, the dielectric landing pad width, and the spacer width.

Abstract: A double-polysilicon, self-aligned bipolar transistor has a collector region formed in a doped semiconductor substrate, an intrinsic counterdoped base formed on the surface of the substrate and a doped intrinsic emitter formed in the surface of the intrinsic base. An etch stop insulator layer overlies the intrinsic base layer above the collector. A base contact layer of a conductive material overlies the etch stop dielectric layer and the intrinsic base layer. A dielectric layer overlies the base contact layer. A wide window extends through the insulator layer and the base contact layer down to the insulator layer. An island or a peninsula is formed in the wide window leaving at least one narrowed window within the wide window, with sidewall spacers in either the wide window or the narrowed window. The narrowed windows are filled with doped polysilicon forming an extrinsic emitter with the intrinsic emitter formed below the extrinsic emitter in the surface of the intrinsic base.

Abstract: A structure and method where C is incorporated into the collector region of a heterojunction bipolar device by a method which does not include C ion implantation are provided. In the present invention, C is incorporated into the collector by epitaxy in a perimeter trench etched into the collector region to better control the carbon profile and location. The trench is formed by etching the collector region using the trench isolation regions and a patterned layer over the center part of the collector as masks. Then, Si:C is grown using selective epitaxy inside the trench to form a Si:C region with sharp and well-defined edges. The depth, width and C content can be optimized to control and tailor the collector implant diffusion and to reduce the perimeter component of parasitic CCB.