Abstract: The invention, in one aspect, provides a method for fabricating a semiconductor device, which includes conducting an etch through an opening in an emitter layer to form a cavity from an underlying oxide layer that exposes a doped tub. A first silicon/germanium (SiGe) layer, which has a Ge concentration therein, is formed within the cavity and over the doped tub by adjusting a process parameter to induce a strain in the first SiGe layer. A second SiGe layer is formed over the first SiGe layer, and a capping layer is formed over the second SiGe layer.

Abstract: The invention, in one aspect, provides a method for fabricating a semiconductor device, which includes conducting an etch through an opening in an emitter layer to form a cavity from an underlying oxide layer that exposes a doped tub. A first silicon/germanium (SiGe) layer, which has a Ge concentration therein, is formed within the cavity and over the doped tub by adjusting a process parameter to induce a strain in the first SiGe layer. A second SiGe layer is formed over the first SiGe layer, and a capping layer is formed over the second SiGe layer.

Abstract: In a semiconductor substrate, a shallow trench isolation structure having a dielectric material disposed in voids of a trench-fill material and a method for forming the shallow trench isolation structure. The voids may be formed during a wet clean process after the dielectric material is formed in the trench. A conformal silicon nitride layer is formed over the substrate and in the voids. After removal of the silicon nitride layer, the voids are at least partially filled by the silicon nitride material.

Abstract: In a semiconductor substrate, a shallow trench isolation structure having a dielectric material disposed in voids of a trench-fill material and a method for forming the shallow trench isolation structure. The voids may be formed during a wet clean process after the dielectric material is formed in the trench. A conformal silicon nitride layer is formed over the substrate and in the voids. After removal of the silicon nitride layer, the voids are at least partially filled by the silicon nitride material.

Abstract: The invention, in one aspect, provides a method of manufacturing a semiconductor device. This aspect includes forming gate electrodes in a non-bipolar transistor region of a semiconductor substrate, placing a polysilicon layer over the gate electrodes in the non-bipolar transistor region and over the semiconductor substrate within a bipolar transistor region. A protective layer is formed over the polysilicon layer. The protective layer has a weight percent of hydrogen that is less than about 9% and is selective to silicon germanium (SiGe), such that SiGe does not form on the protective layer. This aspect further includes forming emitters for bipolar transistors in the bipolar transistor region, including forming a SiGe layer under a portion of the polysilicon layer.

Abstract: In an embodiment, a integrated semiconductor device includes a first Vertical Junction Field Effect Transistor (VJFET) having a source, and a gate disposed on each side of the first VJFET source, and a second VJFET transistor having a source, and a gate disposed on each side of the second VJFET source. At least one gate of the first VJFET is separated from at least one gate of the second VJFET by a channel. The integrated semiconductor device also includes a Junction Barrier Schottky (JBS) diode positioned between the first and second VJFETs. The JBS diode comprises a metal contact that forms a rectifying contact to the channel and a non-rectifying contact to at least one gate of the first and second VJFETs, and the metal contact is an anode of the JBS diode.

Abstract: The invention, in one aspect, provides a method of manufacturing a semiconductor device. This aspect includes forming gate electrodes in a non-bipolar transistor region of a semiconductor substrate, placing a polysilicon layer over the gate electrodes in the non-bipolar transistor region and over the semiconductor substrate within a bipolar transistor region. A protective layer is formed over the polysilicon layer. The protective layer has a weight percent of hydrogen that is less than about 9% and is selective to silicon germanium (SiGe), such that SiGe does not form on the protective layer. This aspect further includes forming emitters for bipolar transistors in the bipolar transistor region, including forming a SiGe layer under a portion of the polysilicon layer.

Abstract: A Lateral Epitaxial Gallium Nitride metal insulator semiconductor field effect transistor (LEGaN-MISFET) is described that includes a body region including at least one layer formed of Gallium Nitride having a first conductivity type formed on the substrate; a resurf layer of Gallium Nitride having a second conductivity type formed the body region; a source region in contact with the resurf layer; a drain region, in contact with the resurf layer and spaced apart from the source region; a gate metal insulator semiconductor (MIS) structure in contact with the body region including a gate contact; and a MIS conductive inversion channel along the surface of the body region in contact with the gate MIS structure. A lateral current conduction path may be formed in the resurf layer between the source region and the drain region connected by the MIS channel, where the lateral current conduction path is controlled by an applied gate source bias.

Abstract: The invention, in one aspect, provides a method of manufacturing a semiconductor device. This aspect includes forming gate electrodes in a non-bipolar transistor region of a semiconductor substrate, placing a polysilicon layer over the gate electrodes in the non-bipolar transistor region and over the semiconductor substrate within a bipolar transistor region. A protective layer is formed over the polysilicon layer. The protective layer has a weight percent of hydrogen that is less than about 9% and is selective to silicon germanium (SiGe), such that SiGe does not form on the protective layer. This aspect further includes forming emitters for bipolar transistors in the bipolar transistor region, including forming a SiGe layer under a portion of the polysilicon layer.

Abstract: Here, we demonstrate new material/structures for the photodetectors, using semiconductor material. For example, we present the Tunable Avalanche Wide Base Transistor as a photodetector. Particularly, SiC, GaN, AlN, Si and Diamond materials are given as examples. The desired properties of an optimum photodetector is achieved. Different variations are discussed, both in terms of structure and material.

Abstract: A method of forming a bipolar device includes forming at least one p-type layer of single crystal silicon carbide and at least one n-type layer of single crystal silicon carbide on a substrate. Stacking faults that grow under forward operation of the device are segregated from at least one of the interfaces between the active region and the remainder of the device. The method of forming bipolar devices includes growing at least one of the epitaxial layers to a thickness greater than the minority carrier diffusion length in that layer. The method also increases the doping concentration of epitaxial layers surrounding the drift region to decrease minority carrier lifetimes therein.

Abstract: The invention, in one aspect, provides a method for fabricating a semiconductor device, which includes conducting an etch through an opening in an emitter layer to form a cavity from an underlying oxide layer that exposes a doped tub. A first silicon/germanium (SiGe) layer, which has a Ge concentration therein, is formed within the cavity and over the doped tub by adjusting a process parameter to induce a strain in the first SiGe layer. A second SiGe layer is formed over the first SiGe layer, and a capping layer is formed over the second SiGe layer.

Abstract: A shallow trench isolation structure having a negative taper angle and a method for forming same. A silicon nitride layer formed over a semiconductor substrate is etched according to a plasma etch process to form a first opening therein having sidewalls that present a negative taper angle. The substrate is etched to form a trench therein underlying the first opening. Silicon dioxide fills both the opening and the trench to form the shallow trench isolation structure, with the silicon dioxide in the opening exhibiting a negative taper angle to avoid formation of conductive stringers during subsequent process steps.

Abstract: A integrated circuit system including providing an integrated circuit device, forming an undoped insulating layer over the integrated circuit device, forming a thin insulating layer over the undoped insulating layer, forming a doped insulating layer over the thin insulating layer, and forming a contact in the undoped insulating layer, thin insulating layer and the doped insulating layer.

Abstract: The invention, in one aspect, provides a method of manufacturing a semiconductor device. This method includes providing a semiconductor substrate and depositing a metal layer over the semiconductor substrate that has an overall thickness of about 1 micron or greater. The metal layer is formed by depositing a first portion of the thickness of the metal layer, which has a compressive or tensile stress associated therewith over the semiconductor substrate. A stress-compensating layer is deposited over the first portion, such that the stress-compensating layer imparts a stress to the first portion that is opposite to the compressive or tensile stress associated with the first portion. A second portion of the thickness of the metal layer is then deposited over the stress-compensating layer.

Abstract: A semiconductor device is described that operates as an improved junction field effect transistor (JFET). A bipolar transistor with a collector region, a base region, an emitter region, a first base contact, and a second base contact insulated from the first base contact, has the base region lightly doped to about a 1E16 to 5E17 atoms/cm3 doping level. A connection is provided between the emitter region and the collector region to act as a JFET gate contact for the bipolar transistor. The semiconductor device operates as an improved JFET with the first base contact being a drain contact and the second base contact being a source contact. A method for manufacture of an improved JFET on a chip containing conventional bipolar devices is also described. The improved JFET is shown being used with a write head in a disk drive system for providing electrostatic discharge protection.

Abstract: One time programmable memory devices are disclosed that are programmed using hot carrier induced degradation to alter one or more transistors characteristics. A one time programmable memory device is comprised of an array of transistors. Transistors in the array are selectively programmed using hot carrier induced changes in one or more transistor characteristics, such as changes to the saturation current, threshold voltage or both, of the transistors. The changes to the transistor characteristics are achieved in a similar manner to known hot carrier transistor aging principles. The disclosed one time programmable memory devices are small and programmable at low voltages and small current.

Abstract: The present invention provides a trench isolation structure, a method for manufacturing a trench isolation structure, and a method for manufacturing an integrated circuit including the trench isolation structure. In one aspect, the method includes forming a hardmask over a substrate, etching a trench in the substrate through the hardmask, forming a liner in the trench, depositing an interfacial layer over the liner within the trench and over the hardmask and filling the trench with a dielectric material.

Abstract: The present invention provides an interconnect that can be employed in an integrated circuit. The interconnect includes a metal line located over a substrate, a dielectric layer located over the metal line, and an interconnect located in the dielectric layer, including a landed portion located over the metal line and an unlanded portion located along at least a portion of a lateral edge of the metal line. The unlanded portion is at least partially filled with a polymer, and the landed portion is substantially filled with a conductive material. A method for manufacturing the interconnect is also provided.

Abstract: In a semiconductor substrate, a shallow trench isolation structure having a dielectric material disposed in voids of a trench-fill material and a method for forming the shallow trench isolation structure. The voids may be formed during a wet clean process after the dielectric material is formed in the trench. A conformal silicon nitride layer is formed over the substrate and in the voids. After removal of the silicon nitride layer, the voids are at least partially filled by the silicon nitride material.