Abstract: A touch display panel and a touch display device are provided. The touch display panel includes: a substrate, a light-emitting device layer arranged on the substrate, and multiple touch electrodes arranged on the side of the light-emitting device layer away from the substrate. The light-emitting device layer includes multiple pixels, and each of the pixels has a light-emitting region and a non-light-emitting region on the periphery of the light-emitting region. Each of the touch electrodes has a structure of a metal grid. The pixels include first color pixels, and grid lines of the metal grid are arranged in each of the non-light-emitting regions of at least a part of the first color pixels.

Abstract: A vertical, single column compound semiconductor bipolar junction transistor device includes an all-around extrinsic base. Aspect ratio trapping is employed during fabrication of the transistor device on a silicon substrate. Homojunction and heterojunction devices are formed using III-V materials with appropriate bandgaps. The emitter of the device may be electrically connected by a lateral buried metal contact.

Abstract: A method for fabricating bipolar junction transistor (BJT) includes the steps of: providing a substrate having an emitter region, a base region, and a collector region; performing a first implantation process to form a first well region in the base region; and performing a second implantation process to form a second well region in the emitter region. Preferably, the first well region and the second well region comprise different concentration.

Abstract: A vertical, single column compound semiconductor bipolar junction transistor device includes an all-around extrinsic base. Aspect ratio trapping is employed during fabrication of the transistor device on a silicon substrate. Homojunction and heterojunction devices are formed using III-V materials with appropriate bandgaps. The emitter of the device may be electrically connected by a lateral buried metal contact.

Abstract: The present invention is directed to a method for forming multiple active components, such as bipolar transistors, MOSFETs, diodes, etc., on a semiconductor substrate so that active components with higher operation voltage may be formed on a common substrate with a lower operation voltage device and incorporating the existing proven process flow of making the lower operation voltage active components. The present invention is further directed to a method for forming a device of increasing operation voltage over an existing device of same functionality by adding a few steps in the early manufacturing process of the existing device therefore without drastically affecting the device performance.

Abstract: A printed electrical connection structure includes a substrate having one or more electrical connection pads and a micro-transfer printed component having one or more connection posts. Each connection post is in electrical contact with a connection pad. A resin is disposed between and in contact with the substrate and the component. The resin has a reflow temperature less than a cure temperature. The resin repeatedly flows at the reflow temperature when temperature-cycled between an operating temperature and the reflow temperature but does not flow after the resin is exposed to a cure temperature. A solder can be disposed on the connection post or the connection pad. After printing and reflow, the component can be tested and, if the component fails, another component is micro-transfer printed to the substrate, the resin is reflowed again, the other component is tested and, if it passes the test, the resin is finally cured.

Abstract: The disclosed technology generally relates to forming patterns of doped semiconductor regions, and more particularly to methods of forming such patterns in fabricating photovoltaic devices. In one aspect, a method of forming a pattern of different doped regions at the same side of a semiconductor substrate comprises providing a patterned doped layer on a surface of the semiconductor substrate at predetermined locations where at least one first doped region is to be formed. The method additionally includes selectively growing at least one second doped region epitaxially at the same side of the semiconductor substrate using the patterned doped layer as an epitaxial growth mask. Furthermore, selectively growing comprises driving dopants from the patterned doped layer into the semiconductor substrate to form the first doped region at the predetermined locations.

Abstract: A method of forming a heterojunction bipolar transistor. The method includes providing a structure comprising at least an intrinsic base region and an emitter pedestal region. A stack is formed on the intrinsic base region. The stack comprises a polysilicon layer and a top sacrificial oxide layer. A trench is formed in the structure. The trench circumscribes the intrinsic base region and the stack. An extrinsic base is formed at two regions around the stack. The extrinsic base is formed by a selective epitaxial growth process to create a bridge over the trench. The bridge connects the two regions. An opening is provided in the stack. The opening exposes a portion of the intrinsic base region. An emitter is formed in the opening.

Abstract: A semiconductor component includes a semiconductor body, in which are formed: a substrate of a first conduction type, a buried semiconductor layer of a second conduction type arranged on the substrate, and a functional unit semiconductor layer of a third conduction type arranged on the buried semiconductor layer, in which at least two semiconductor functional units arranged laterally alongside one another are provided. The buried semiconductor layer is part of at least one semiconductor functional unit, the semiconductor functional units being electrically insulated from one another by an isolation structure which permeates the functional unit semiconductor layer, the buried semiconductor layer, and the substrate. The isolation structure includes at least one trench and an electrically conductive contact to the substrate, the contact to the substrate being electrically insulated from the functional unit semiconductor layer and the buried layer by the at least one trench.

Abstract: A photovoltaic (PV) cell device comprises a first semiconductor substrate; a second semiconductor substrate bonded to the first semiconductor substrate; an insulating layer provided between the first and second substrates to electrically isolate the first substrate from the second substrate; a plurality of PV cells defined on the first substrate, each PV cell including a n-type region and a p-type region; a plurality of vertical trenches provided in the first substrate to separated the PV cells, the vertical trenches terminating at the insulating layer; a plurality of isolation structures provided within the vertical trenches, each isolation structure including a first isolation layer including oxide and a second isolation layer including polysilicon; and an interconnect layer patterned to connect the PV cells to provide X number of PV cells in series and Y number of PV cells in parallel.

Abstract: In a semiconductor device having an LDMOSFET, a source electrode is at the back surface thereof. Therefore, to reduce electric resistance between a source contact region in the top surface and the source electrode at the back surface, a poly-silicon buried plug is provided which extends from the upper surface into a P+-type substrate through a P-type epitaxial layer, and is heavily doped with boron. Dislocation occurs in a mono-crystalline silicon region around the poly-silicon buried plug to induce a leakage failure. The semiconductor device has a silicon-based plug extending through the boundary surface between first and second semiconductor layers having different impurity concentrations. At least the inside of the plug is a poly-crystalline region. Of the surface of the poly-crystalline region, the portions located on both sides of the foregoing boundary surface in adjacent relation thereto are each covered with a solid-phase epitaxial region.

Abstract: A semiconductor device includes a lower substrate, a thin semiconductor layer and an insulating layer formed between the lower substrate and the semiconductor layer. An active transistor area is formed with a base formed along a surface of the semiconductor layer, an emitter region formed in the base, a buried collector in the thin semiconductor layer to contact the insulating layer, a collector contacting the buried collector, and emitter, collector and base contacts. The active transistor area is configured to operate at an emitter current at least in the order of mA (milli-ampere). An isolation trench extends through the semiconductor layer to the insulating layer and surrounds the active transistor area with a distance in the order of ?m (micron) from the active transistor area and with a space area of more than 50 ?m2 between the active transistor area and the isolation trench.

Abstract: A wafer processing method having a step of reducing the thickness of a wafer in only a device forming area where semiconductor chips are formed by grinding and etching the back side of the wafer to thereby form a recess on the back side of the wafer. At the same time, an annular projection is formed around the recess to thereby ensure the rigidity of the wafer. Accordingly, handling in shifting the wafer from the back side recess forming step to a subsequent step of forming a back side rewiring layer can be performed safely and easily.

Abstract: A trench metal oxide semiconductor field effect transistor (MOSFET) with a terraced trench gate. An epitaxial layer with a plurality of trenches is provided and a gate oxide layer is covered the sidewalls and bottoms of the trenches. A polysilicon layer is filled in the trenches, wherein the polysilicon layer is higher than the sidewalls of the trenches to be used as a gate of the MOSFET. A plurality of sources and bodies are formed in the epitaxial layer, and the bodies at both sides of the trenches. An insulating layer is covered on the substrate, wherein a plurality of metal contact windows are provided. Metal plugs are filled in the metal contact windows to form metal connections for the MOSFET.

Abstract: A voltage-controlled semiconductor inductor and method is provided. According to various embodiments, the voltage-controlled inductor includes a conductor configured with a number of inductive coils. The inductor also includes a semiconductor material having a contact with at least a portion of at least one of the coils. The semiconductor material is doped to form a diode with a first doped region of first conductivity type, a second doped region of second conductivity type, and a depletion region. A voltage across the diode changes lengths of the first doped region, the second doped region and the depletion region, and adjacent coils in contact with at least one of the doped regions are electrically shorted, thereby varying the inductance of the inductor. In various embodiments, the inductor is electrically connected to a resistor and a capacitor to provide a tunable RLC circuit. Other aspects and embodiments are provided herein.

Abstract: A device includes a top layer having at least two opposing faces, and at least two epitaxially deposited layers, each of the at least two epitaxially deposited layers situated on a respective one of the at least two opposing faces, a combined thickness of the at least two epitaxially deposited layers tuning a gap between the at least two opposing faces.

Abstract: A method and system for providing a bipolar transistor is described. The method and system include providing a compound base region, providing an emitter region coupled with the compound base region, and providing a collector region coupled with the compound base region. The bipolar transistor may also include at least one other predetermined portion. The method and system also include providing at least one predetermined amount of oxygen to at least one of the compound base region, the emitter region, the collector region, and the predetermined portion of the bipolar transistor.

Abstract: The invention includes BIFETRAM devices. Such devices comprise a bipolar transistor in combination with a field effect transistor (FET) in a three-dimensional stacked configuration. The memory devices can be incorporated within semiconductor-on-insulator (SOI) constructions. The base region of the bipolar device can be physically and electrically connected to one of the source/drain regions of the FET to act as a storage node for the memory cell. The semiconductor material of the SOI constructions can comprise Si/Ge, and the active region of the FET can extend into the Si/Ge. The SOI constructions can be formed over any of a number of substrates, including, for example, semiconductive materials, glass, aluminum oxide, silicon dioxide, metals and/or plastics.

Abstract: An antifuse device (120) that includes a bias element (124) and an programmable antifuse element (128) arranged in series with one another so as to form a voltage divider having an output node (F) located between the bias and antifuse elements. When the antifuse device is in its unprogrammed state, each of the bias element and antifuse element is non-conductive. When the antifuse device is in its programmed state, the bias element remains non-conductive, but the antifuse element is conductive. The difference in the resistance of the antifuse element between its unprogrammed state and programmed state causes the difference in voltages seen at the output node to be on the order of hundreds of mili-volts when a voltage of 1 V is applied across the antifuse device. This voltage difference is so high that it can be readily sensed using a simple sensing circuit (228).

Abstract: An interfacial oxide layer (185) is formed in the emitter regions of the NPN transistor (280, 220) and the PNP transistor (290, 200). Fluorine is selectively introduced into the polysilicon emitter region of the NPN transistor (220) to reduce the 1/f noise in the NPN transistor.

Abstract: A Bipolar Junction Transistor (BJT) that reduces the variation in the current gain through the use of a trench pullback structure. The trench pullback structure is comprised of a trench and an active region. The trench reduces recombination in the emitter-base region through increasing the distance charge carriers must travel between the emitter and the base. The trench also reduces recombination by reducing the amount of interfacial traps that the electrons injected from the emitter are exposed to. Further, the trench is pulled back from the emitter allowing an active region where electrons injected from a sidewall of the emitter can contribute to the overall injected emitter current. This structure offers the same current capability and current gain as a device without the trench between the emitter and the base while reducing the current gain variation.

Abstract: An electronic circuit comprises a bipolar transistor that includes a conductive back electrode, an insulator layer over the conductive back electrode and a semiconductor layer of either an n-type or p-type material over the insulator layer. The semiconductor layer includes a doped region, used as the collector and a heavily doped region, bordering the doped region, used as a reachthrough between the insulator layer and the collector contact electrode. A majority-carrier accumulation layer is induced adjacent to the insulator in the doped region of the collector by the application of a bias voltage to the back electrode.

Abstract: The present invention is drawn to a method and a system for creating a sub-1V bandgap reference (BGR) circuit. In particular, a sub-1V BGR circuit is formed comprising a shallow trench isolation (STI) region and a poly silicon region above said STI region. The poly silicon region is formed having a first doped region longer than a second doped region. The poly silicon region as one single structure is adapted to function as a resistor and a diode coupled in series, said structure adapted to generate currents in a feedback loop to generate a BGR voltage. In forming the sub-1V BGR circuit, a silicide blocking mask (already available in the process flow for forming a standard semiconductor device) is used to prevent spacer oxide from forming above the center portion of the poly silicon region. In turn, silicide contacts can be formed away from the center portion of the poly silicon region.

Abstract: Existing polysilicon emitter technology is used to contact poly fill in a trench isolation structure. A standard single poly emitter window process is followed. An “emitter window” is masked directly over the polysilicon trench fill. Heavily doped single emitter poly is deposited and masked over the entire active region. The standard emitter drive then diffuses dopant through the emitter window into the undoped trench poly fill to provide an ohmic contact between the emitter poly and the trench poly fill. Contact to the emitter poly is made from overlying metal.

Abstract: An integrated dynamic memory cell having a small area of extent on a semiconductor substrate is described. The memory cell has a selection MOSFET with a gate connection area that is connected to a word line, a source connection doping area which is connected to a bit line, and a drain connection doping area. A memory MOSFET has a gate connection area which is connected via a thin dielectric layer to a connection doping region which connects a source connection doping area of the memory MOSFET to the drain connection doping area of the selection MOSFET. The memory MOSFET further has a drain connection doping area that is connected to a supply voltage. The selection and memory MOSFETs are disposed on opposite sidewalls of a trench, which is etched in the substrate, and the connection doping region forms a bottom of the trench.

Abstract: A semiconductor projection is formed on a semiconductor substrate of the first conductivity type and has a semiconductor layer of the first conductivity type. The semiconductor projection has a top surface and side surfaces. A gate electrode is formed above at least the side surfaces of the semiconductor projection. Source and drain regions are formed in the side surfaces of the semiconductor projection on opposite sides of the gate electrode. First and second device isolation insulating films are formed on the semiconductor substrate on opposite sides of the semiconductor projection. A first impurity region is formed in the semiconductor substrate below the first device isolation insulating film. A second impurity region is formed in the semiconductor substrate below the second device isolation insulating film. The first and second impurity regions are in contact with each other in the semiconductor substrate below the semiconductor projection.

Abstract: An integrated circuit on a silicon substrate includes at least one polysilicon line and at least one antistatic contact connecting the polysilicon line to the silicon substrate. The antistatic contact includes a thin oxide layer between the polysilicon line and the silicon substrate. The thin oxide layer is of a sufficiently small thickness so that a current flows across it by the tunnel effect when the polysilicon line is brought, relatively to the substrate, to a voltage greater or less than determined thresholds.

Abstract: An integrated circuit is fabricated with a layer of polysilicon located on top of shallow trench regions. The polysilicon is patterned so that the trench features are not exposed during an etching operation performed on the polysilicon layer. The process of fabricating transistor gate electrodes, therefore, is improved by reducing etch byproducts contributed by the shallow trench region features.

Abstract: Lateral bipolar transistor, in which a thin diffusion barrier (4) is applied to a base region (10) between an emitter region (9) and a collector region (11), and there is present, on said barrier, a base electrode (8) which is provided for low-resistance supply, is connected to a heavily doped base terminal region and consists of polysilicon, for example, into which dopant is diffused out from said base terminal region.

Abstract: A lateral bipolar transistor includes a semiconductor layer overlying an electrically insulating material and an insulating layer overlying a central portion of the semiconductor layer. A contact hole resides in the insulating layer and a conductive material overlies the insulating layer and makes electrical contact with the semiconductor layer through the contact hole, thereby forming a base contact. The semiconductor layer has a first conductivity type in a central region which substantially underlies the conductive material, and has a second conductivity type in regions adjacent the central region. The first region forms a base region and the adjacent regions form a collector region and an emitter region, respectively. A method of forming a lateral bipolar transistor device is also disclosed. The method includes forming a semiconductor layer over an insulating material and forming an insulating layer over the semiconductor material.

Abstract: The invention relates to semiconductor devices having a bipolar transistor to form an isolation area within a base electrode contact area to ensure stable contact of the base electrode. The bipolar transistor formed in the transistor area is in the form of an island and is rectangular when view from above. The isolation area is formed of a dielectric material around the transistor area, and the base area is formed around the emitter area which forms the central area of the transistor area. A contact groove is formed at the inner interface of the isolation groove which faces the outer surface of the transistor area, and a part of the base electrode is buried in the contact groove and faces at least one of the upper surface of the transistor area and an inner surface of the contact groove.

Abstract: A bipolar transistor is vertically isolated from underlying silicon by an isolation layer of conductivity type opposite that of the collector. This isolation layer lies beneath the heavily doped buried layer portion of the collector, and is formed either by ion implantation prior to epitaxial growth of well regions, or by high energy ion implantation into the substrate prior to formation of the well and the heavily doped buried collector layer. Utilization of trench lateral isolation extending into the semiconductor material beyond the isolation layer permits blanket implant of the isolation layer, obviating the need for an additional masking step.

Abstract: A silicon-comprising layer is employed adjacent a trench during planarization of an oxide fill within the trench. An overhanging oxide sidewall is formed along a lateral edge of a trenched isolation region, the overhanging oxide sidewall overlapping an upper surface of a substrate immediately adjacent the trenched isolation region. An oxide plug is formed comprising a recessed portion below a substrate upper surface and an elevated portion above the substrate upper surface. The elevated portion comprising a ledge which extends over the substrate upper surface and has a top surface and a substantially vertical lateral edge side surface. Further, the plug may be within a substrate, the oxide plug having a recessed portion below a substrate upper surface and an elevated portion above the substrate upper surface, the elevated portion comprising a ledge extending over the substrate upper surface and abutting a polysilicon layer.

Abstract: A method is provided for maximizing substrate usage in the fabrication of flat panel displays or detectors, while also maximizing electrostatic protection for the displays or detectors. Initially, at least two detectors are positioned on the substrate, with each of the detectors having a guard ring of a certain width. At least a section of the guard ring width of one detector is approximately adjacent to a section of the guard ring width of another detector. The approximately adjacent guard ring width sections are then positioned such that a maximum overlap of the adjacent guard ring width sections is achieved, while still providing each display or detector with electrostatic discharge protection. Each of the detectors is separated from the other detectors and the remainder of the substrate by the process of scribing partially through the substrate and breaking at the scribe mark or by sawing.

Abstract: A bipolar semiconductor device includes an npn transistor using a base outlet electrode in the form of a polycrystalline Si film and one or more other devices using an electrode in the form of a polycrystalline Si film supported on a common p-type Si substrate, the sheet resistance of the polycrystalline Si film forming the base outlet electrode of the npn transistor is decreased to two thirds of the sheet resistance of the polycrystalline Si film forming at least one electrode of at least one other device. The base outlet electrode can be made by first making the polycrystalline Si film on the entire surface of the substrate, then applying selective ion implantation of Si to a selective portion of the polycrystalline Si film for making the base outlet electrode to change it into an amorphous state, and then annealing the product to grow the polycrystalline Si film by solid-phase growth.

Abstract: A sensor element provided with a silicon substrate having a semiconductor circuit, a sensing-element portion formed on the silicon substrate and connected to the semiconductor circuit, and a cavity portion formed by removing a silicon substrate portion below the sensing-element portion, in which a removal resistance region having resistance against substrate removal is provided in the silicon substrate between the semiconductor circuit and the cavity portion.

Abstract: A junction diode structure formed within an integrated circuit. The junction diode structure comprises a semiconductor substrate. The junction diode structure also comprises a dielectric layer formed over the semiconductor substrate. In addition, the junction diode structure also comprises a first polysilicon layer formed upon the dielectric layer, where the first polysilicon layer has a first dopant polarity and a first dopant concentration. Finally, the junction diode structure comprises a second polysilicon layer formed at least in part overlapping and at least in part in contact with the first polysilicon layer. The second polysilicon layer has a second dopant polarity and a second dopant concentration, where the second dopant polarity is opposite to the first dopant polarity, and where a first portion of the second polysilicon layer overlapping and in contact with a first portion of the first polysilicon layer forms a junction diode within the junction diode structure.

Abstract: A semiconductor device, polysilicon-contacted trench isolation- structure that provides improved electrical isolation stability, a method of operating a polysilicon-contacted trench isolated semiconductor device, and a process for manufacturing a polysilicon-contacted trench isolation structure. The trench isolation structure includes an isolation trench formed in a semiconductor substrate. The isolation trench has a layer of trench lining oxide, a layer of trench lining silicon nitride and a trench fill polysilicon (poly 1) layer. Exposed lateral surfaces of the poly 1, which extend above the trench lining silicon nitride, are contacted to another layer of polysilicon (poly 2). The method of operation includes applying a bias voltage to the trench fill poly 1 layer via poly 2. The process for manufacture includes etching an isolation trench that extends through a layer of field oxide and into a semiconductor substrate.

Abstract: A BiCMOS structure and a method for making the same is disclosed, where the dielectric layer between the emitter electrode and the base region is formed of a deposited dielectric. After definition of the bipolar and MOS moat regions, a layer of polysilicon is deposited thereover, and removed from the bipolar region. The base implant is performed either prior to or after the etch of the polysilicon layer. A layer of TEOS oxide is formed thereover and is etched to remain in portions of the bipolar region, with an emitter contact formed therethrough and a portion of the bipolar region exposed at which the extrinsic base is formed. An alternative embodiment of the invention includes scaling the emitter contact by forming sidewall oxide filaments therewithin. A second layer of polysilicon is disposed thereover to form the emitter electrode, and to merge with the first layer to form the gates of the MOS transistors.

Abstract: A manufacturing method of the present invention comprises the first step of forming an epitaxial base layer in an opening of an element-isolating oxide film on a semiconductor substrate in a non-selection condition, the second step of growing a silicon oxide film on the epitaxial base layer and a base polysilicon layer, and the third step of etching the silicon oxide film to expose the polysilicon layer by the etch-back or the CMP. According to this method, the silicon oxide film is left only on the epitaxial base layer, and the planarization of the device can be attained. The present invention also reduces the resistance of the base electrode by providing silicide to the device.

Abstract: A collector structure in a bipolar transistor on a semiconductor substrate is surrounded by trench isolations. A well region has a first impurity concentration and extends in an upper portion of the semiconductor substrate surrounded by the trench isolations. The well region is a first conductivity type and a burying layer horizontally extends under the well region. The burying layer is positioned shallower than the bottom of the trench isolations. Collector plug electrodes extend in a vertical direction and along inside walls of the trench isolations. The collector plug electrodes are the first conductivity type and have a second impurity concentration higher than the first impurity concentration. The collector plug electrodes have a bottom level which is about the same as the bottom of the trench isolations. A collector diffusion layer extends in a vertical direction and along inside vertical walls of the collector plug electrodes.

Abstract: In a semiconductor device having regions of a vertical pnp bipolar transistor, that is, a collector region composed of a p-type semiconductor region, a base region composed of an n-type semiconductor region and an emitter region composed of a p-type semiconductor region, a metal electrode is connected to the base region with polysilicon doped with impurities being provided therebetween. In another form of a semiconductor device, an n.sup.+ region is provided within a base region of a vertical pnp bipolar transistor while surrounding an emitter region of the transistor.

Abstract: The present invention is directed to a semiconductor device having an ohmic contact to a buried layer. The device includes a device wafer having on its first surface a first dielectric layer and on its second surface a doped epitaxial layer that comprises a dopant having a first polarity. The device also includes a doped first layer that is contiguous to the dielectric layer and comprises a dopant having a first polarity. The semiconductor device of the present invention further comprises a plurality of trenches, each having spaced apart sidewalls and extending from an upper surface of the epitaxial layer through the epitaxial layer to a trench floor. At least a portion of the trenches include a layer of doped semiconductor material disposed on the sidewalls. This layer provides electrical contact between the doped first layer of first polarity and a surface collector region, also of first polarity, of the epitaxial layer.

Abstract: A semiconductor device and a manufacturing method therefor which can simultaneously realize both a reduction in base transit time by a reduction in base width and a reduction in base resistance by a reduction in link base resistance. The semiconductor device is manufactured by the method including the steps of forming a first impurity diffused layer of a first conduction type in a semiconductor substrate; forming a conducting film connected to the first impurity diffused layer; forming a first insulating film on the conducting film; forming a first hole through a laminated film composed of the first insulating film and the conducting film; forming a second impurity diffused layer of the first conduction type in the semiconductor substrate exposed to the first hole; forming a side wall from a second insulating film in the first hole to form a second hole; and forming a third impurity diffused layer of the first conduction type in the semiconductor substrate exposed to the second hole.

Abstract: A structure and method of maximizing the volume of low dielectric constant material between adjacent traces of a conductive interconnect structure. A semiconductor structure includes a semiconductor substrate, a first insulating layer located over the semiconductor substrate, a conductive interconnect layer having a plurality of conductive traces located over the first insulating layer, and a patterned insulating layer located over the patterned interconnect layer. One or more trenches are formed in the upper surface of the first insulating layer. These trenches, which do not extend completely through the first insulating layer, are located between adjacent traces of the interconnect layer. A dielectric material having a low dielectric constant is located in these trenches, and between adjacent traces of the patterned interconnect layer. The trenches advantageously maximize the volume of low dielectric constant material which is located between the traces.

Abstract: A semiconductor device includes a groove formed in a surface of a first semiconductor substrate of one conductivity type in order to partition and isolate first and second device regions. A first insulating film on the first semiconductor substrate of the first device region also contacts the groove. A second insulating film covers an inner wall of the groove. The first insulating film is thicker than the second film in order to increase the breakdown voltage and facilitate carrying a higher current. This thickness relationship also aids manufacturing.

Abstract: A heterojunction bipolar transistor in an integrated circuit has intrinsic and extrinsic base portions. The intrinsic base portion substantially comprises epitaxial silicon-germanium alloy. The extrinsic base portion substantially comprises polycrystalline material, and contains a distribution of ion-implanted impurities. An emitter overlies the intrinsic base portion, and a spacer at least partially overlies the emitter. The spacer overhangs the extrinsic base portion by at least a distance characteristic of lateral straggle of the ion-implanted impurities.

Abstract: A silicon-comprising layer is employed adjacent a trench during planarization of an oxide fill within the trench. An overhanging oxide sidewall is formed along a lateral edge of a trenched isolation region, the overhanging oxide sidewall overlapping an upper surface of a substrate immediately adjacent the trenched isolation region. An oxide plug is formed comprising a recessed portion below a substrate upper surface and an elevated portion above the substrate upper surface. The elevated portion comprising a ledge which extends over the substrate upper surface and has a top surface and a substantially vertical lateral edge side surface. Further, the plug may be within a substrate, the oxide plug having a recessed portion below a substrate upper surface and an elevated portion above the substrate upper surface, the elevated portion comprising a ledge extending over the substrate upper surface and abutting a polysilicon layer.

Abstract: A bipolar transistor is provided whose emitter surrounds the base. The transistor has in some embodiments a high ratio of the emitter area to the base area and low collector and emitter resistances. Further, a transistor is provided in which a collector contact region is surrounded by the base. Consequently, a low collector resistance is obtained in some embodiments.

Abstract: A semiconductor device comprises a semiconductor substrate having a main surface, a first semiconductor region of a first conductive type, formed on the main surface of the semiconductor substrate, a surrounding of the first semiconductor region is buried with a first insulation film, a second semiconductor region of a second conductive type, formed on the first insulation film and the first semiconductor region, a second insulation film, formed on the second semiconductor region, an end portion of the second insulation film is positioned above the first insulation film, and having an opening at a central portion thereof to be positioned above the first semiconductor region, and a third semiconductor region of a first conductivity type formed on a surface of the second semiconductor region exposed through the opening of the second insulation film.