Abstract: A field effect transistor configured for use in high power applications and a method for its fabrication is disclosed. The field effect transistor is formed of III-V materials and is configured to have a breakdown voltage that is advantageous for high power applications. The field effect transistor is so configured by determining the operating voltage and the desired breakdown voltage for that operating voltage. A peak electric field is then identified that is associated with the operating voltage and desired breakdown voltage. The device is then configured to exhibit the identified peak electric field at that operating voltage. The device is so configured by selecting device features that control the electrical potential in the device drift region is achieved. These features include the use of an overlapping gate or field plate in conjunction with a barrier layer overlying the device channel, or a p-type pocket formed in a region of single-crystal III-V material formed under the device channel.

Abstract: A field effect transistor configured for use in high power applications and a method for its fabrication is disclosed. The field effect transistor is formed of III-V materials and is configured to have a breakdown voltage that is advantageous for high power applications. The field effect transistor is so configured by determining the operating voltage and the desired breakdown voltage for that operating voltage. A peak electric field is then identified that is associated with the operating voltage and desired breakdown voltage. The device is then configured to exhibit the identified peak electric field at that operating voltage. The device is so configured by selecting device features that control the electrical potential in the device drift region is achieved. These features include the use of an overlapping gate or field plate in conjunction with a barrier layer overlying the device channel, or a p-type pocket formed in a region of single-crystal III-V material formed under the device channel.

Abstract: A heterojunction bipolar transistor includes an emitter or collector region of doped silicon, a base region including silicon-germanium, and a spacer. The emitter or collector region form a heterojunction with the base region. The spacer is positioned to electrically insulate the emitter or collector region from an external region. The spacer includes a silicon dioxide layer physically interposed between the emitter or collector region and the remainder of the spacer.

Abstract: A heterojunction bipolar transistor includes an emitter or collector region of doped silicon, a base region including silicon-germanium, and a spacer. The emitter or collector region form a heterojunction with the base region. The spacer is positioned to electrically insulate the emitter or collector region from an external region. The spacer includes a silicon dioxide layer physically interposed between the emitter or collector region and the remainder of the spacer.

Abstract: An integrated circuit with a buried layer for increasing the Q of an inductor formed in the integrated circuit. The substrate includes a highly doped buried preserving device and latchup characteristics. The inductor may also include an increased thickness conductive layer in the inductor to further increase Q. The present invention is also directed to a low loss interconnect.

Abstract: A process for device fabrication in which amorphous silicon is deposited into a narrow gap is disclosed. The gap is an opening between two layers of material. The gap results when a window is formed in one of the two layers and a portion of a third layer at the base of the window is removed. In the formation of a bipolar device, a layer of oxide is formed on a silicon substrate and a layer of silicon is formed on the oxide layer which serves as the extrinsic base for the device. In the bipolar device, a window is formed in the polysilicon and the oxide layer at the base of the window is then removed. In the bipolar device, the silicon substrate underlies the gap and the extrinsic base silicon overlies the gap. When the oxide is removed from the base of the window, a portion of the oxide layer underlying the extrinsic base silicon is removed as well, thereby forming a gap between the extrinsic base silicon and the underlying silicon substrate.

Abstract: A device with at least one noise-sensitive element, at least one noise-generating element, and a porous silicon barrier in the substrate is disclosed. The porous silicon barrier isolates the noise-sensitive element from the signals coupled into the substrate by the noise-generating element. A process for making this device is also disclosed.

Abstract: In order to reduce the rate of (hot charge-carrier) degradation of semiconductor devices formed in a semiconductor body, a neutral impurity--such as germanium in silicon MOS transistors--is introduced into the body in a neighborhood of an intersection of a p-n junction with a surface of the body.

Abstract: A test circuit is described for measuring the specific contact resistivity r.sub.c of self-aligned electrodes contacting underlying diffused regions at a major surface of an underlying semiconductor wafer, as well as the sheet (lateral) resistance r.sub.s of the underlying diffused regions in some embodiments. The test circuit illustratively includes a pair of test MOS or other type of transistors advantageously made by a self-aligned metallization process simultaneously with the other MOS or other type of transistors to be tested. The two test transistors share a common diffused region, a self-aligned common controlled electrode contacting a diffused region underneath it, and a common control electrode. During test operation, both est transistors are kept ON by means of an applied above-threshold control voltage, while a current source forces current through one of the transistors.

Abstract: A new SOI device which permits both the kink effect to be avoided and threshold voltage to be regulated, as well as a new method for fabricating SOI ICs, is disclosed. The new device included an electrically conductive pathway extending from the active volume and terminating in a non-active region of the substrate of the device. A back-gate bias is communicated to, and kink-inducing charges are conducted away from, the active volume through the conductive pathway. The new fabrication methd permits SOI ICs to be fabricated using available circuit designs and pattern delineating apparatus, e.g., IC mask sets. This method involves the formation of a precursor substrate surface which includes islands of insulating material, each of which is encircled by a crystallization seeding area of substantially single crystal semiconductor material. The boundaries of the islands are defined with a first pattern delineating device, e.g.

Abstract: One or more silicon-integrated-circuit chips are attached, active side up, to the bottom side of a silicon wafer. A sloped-wall through-aperture is etched in the wafer in registry with a portion of the active side of each attached chip. A lithographically defined conductive pattern is then formed on the top side of the wafer and on the sloped walls to connect conductive pads on each chip to conductive pads on other chips and/or to conductive terminals disposed along the periphery of the wafer. The resulting packaged chip assembly has advantageous performance and cost characteristics.

Abstract: One or more silicon-integrated-circuit chips are attached, active side up, to the top side of a silicon wafer. The top side of the wafer and all but peripheral portions of the attached chip(s) are then coated with an etch-resistant layer. Subsequently, the chips are etched to form sloped edges between the active areas of the chips and the top side of the wafer. A lithographically defined conductive pattern is then formed on the top side of the wafer and on the sloped edges to connect conductive pads on each chip to conductive pads on other chips and/or to conductive terminals disposed along the periphery of the wafer. In other embodiments, at least one chip of the type described is attached to each side of a wafer. In such embodiments, connections can also be made through vias in the wafer to selectively interconnect pads and/or terminals included on both sides of the wafer. The resulting packaged chip assembly has advantageous performance and cost characteristics.