Abstract: A heterojunction bipolar transistor includes a substrate, a semiconductor unit, an electrode unit and a dielectric layer. The semiconductor unit includes a collector layer, a base layer and an emitter layer sequentially formed on the substrate in such order. The electrode unit includes a collector electrode, a base electrode, and an emitter electrode respectively disposed on the collector layer, the base layer and the emitter layer. The dielectric layer covers and cooperates with the emitter layer to define an opening extending therethrough and terminating at the base layer to expose a contact region. The base electrode is disposed on the contact region, extends through the opening, and partially covers the dielectric layer.

Abstract: A method and structure for forming semiconductor device includes forming a contact via opening in a first dielectric layer, where the contact via opening exposes a first portion of a contact etch stop layer (CESL). The method further includes etching both the first portion of the CESL exposed by the contact via opening and adjacent lateral portions of the CESL to expose a source/drain contact and form an enlarged contact via opening having cavities disposed on either side of a bottom portion of the enlarged contact via opening. The method further includes forming a passivation layer on sidewall surfaces of the enlarged contact via opening including on sidewall surfaces of the cavities. The method further includes depositing a first metal layer within the enlarged contact via opening and within the cavities to provide a contact via in contact with the exposed source/drain contact.

Abstract: In one example, a method includes performing a first etching process to pattern a dielectric layer and expose a contact etch stop layer, performing a second etching process to remove the etch stop layer and expose a top surface of an underlying feature, performing a third etching process to laterally recess the etch stop layer, and depositing a conductive material over the underlying feature to create a conductive feature in direct contact with the underlying feature.

Abstract: A tunneling transistor and a method of fabricating the same, the tunneling transistor includes a fin shaped structure, a source structure and a drain structure, and a gate structure. The fin shaped structure is disposed in a substrate, and the source structure and the drain structure are disposed the fin shaped structure, wherein an entirety of the source structure and an entirety of the drain structure being of complementary conductivity types with respect to one another and having different materials. A channel region is disposed in the fin shaped structure between the source structure and the drain structure and the gate structure is disposed on the channel region. That is, a hetero tunneling junction is vertically formed between the channel region and the source structure, and between the channel region and the drain structure in the fin shaped structure.

Abstract: The method of manufacturing a structure comprising one or several strained semiconducting zones capable of forming one or several transistor channel regions, the method including the following steps: a) providing a substrate coated with a masking layer wherein there are one or several first slits exposing one or several first oblong semiconducting portions made of a first semiconducting material and extending in a first direction, b) making a second semiconducting material grow with a mesh parameter different from the mesh parameter of the first semiconducting material, so as to form one or several first semiconducting blocks strained along the first direction, on said one or several first oblong semiconducting portions.

Abstract: An integrated optical device fabricated in the back end of line process located within the vertical span of the metal stack and having one or more advantages over a corresponding integrated optical device fabricated in the silicon on insulator layer.

Abstract: Fabrication methods and device structures for bipolar junction transistors and heterojunction bipolar transistors. A first dielectric layer is formed and a second dielectric layer is formed on the first dielectric layer. An opening is etched extending vertically through the first dielectric layer and the second dielectric layer. A collector is formed inside the opening. An intrinsic base, which is also formed inside the opening, has a vertical arrangement relative to the collector.

Abstract: Embodiments provide a method for manufacturing a bipolar junction transistor, comprising: providing a semiconductor substrate comprising a buried layer of a first conductive type; doping the semiconductor substrate in a collector implant region, to obtain a collector implant of the first conductive type extending parallel to a surface of the semiconductor substrate and from the surface of the semiconductor substrate to the buried layer; providing a base layer of a second conductive type on the surface of the semiconductor substrate, the base layer covering the collector implant; providing a sacrificial emitter structure on the base layer, wherein a projection of an area of the sacrificial emitter structure is enclosed by an area of the collector implant; and partially counter doping the collector implant through an area of the base layer surrounding an area of the base layer that is covered by the sacrificial emitter structure.

Abstract: A method of manufacturing a nitride semiconductor device is provided, comprising: forming, on a substrate, a first laminated body where a first nitride semiconductor layer, a second nitride semiconductor layer and a third nitride semiconductor layer are laminated in this order; subsequent to the forming, removing a partial region of the third nitride semiconductor layer, subsequent to the removing; implanting ions to the first nitride semiconductor layer from the partial region where the third nitride semiconductor layer is removed at least through the second nitride semiconductor layer; and subsequent to the implanting the ions, annealing the first laminated body.

Abstract: An ion implantation mask, which is an inorganic insulating film, is formed on a silicon carbide substrate. A mask portion and two regions of an opened ion implantation portion are formed in the ion implantation mask by dry etching. At that time, a residual portion which is thinner than the mask portion is formed in the bottom of the opened ion implantation portion. Then, ions are implanted through the ion implantation mask to form a predetermined semiconductor region in the silicon carbide substrate. According to this structure, it is possible to prevent an increase in the roughness of the surface of the silicon carbide substrate and to improve breakdown voltage.

Abstract: Metal oxynitride diodes having at least a first metal oxynitride layer of a first conduction type and a second metal oxynitride layer of a second conduction type are provided. The first oxynitride layer is selectively doped or un-intentionally doped and have high carrier mobility. The second oxynitride layer is also selectively doped or un-intentionally doped and have high carrier mobility. A compensated oxynitride drift layer having a low carrier density may be adopted to increase the breakdown voltage of the device.

Abstract: A SiGe HBT is disclosed, which includes: a silicon substrate; shallow trench field oxides formed in the silicon substrate; a pseudo buried layer formed at bottom of each shallow trench field oxide; a collector region formed beneath the surface of the silicon substrate, the collector region being sandwiched between the shallow trench field oxides and between the pseudo buried layers; a polysilicon gate formed above each shallow trench field oxide having a thickness of greater than 150 nm; a base region on the polysilicon gates and the collector region; emitter region isolation oxides on the base region; and an emitter region on the emitter region isolation oxides and a part of the base region. The polysilicon gate is formed by gate polysilicon process of a MOSFET in a CMOS process. A method of manufacturing the SiGe HBT is also disclosed.

Abstract: A semiconductor device includes a substrate, a carrier transit layer disposed above the substrate, a compound semiconductor layer disposed on the carrier transit layer, a source electrode disposed on the compound semiconductor layer, a first groove disposed from the back of the substrate up to the inside of the carrier transit layer while penetrating the substrate, a drain electrode disposed in the inside of the first groove, a gate electrode located between the source electrode and the first groove and disposed on the compound semiconductor layer, and a second groove located diagonally under the source electrode and between the source electrode and the first groove and disposed from the back of the substrate up to the inside of the carrier transit layer while penetrating the substrate.

Abstract: Consistent with an example embodiment, a GaN heterojunction structure has a three-layer dielectric structure. The lowermost and middle portions of the gate electrode together define the gate foot, and this is associated with two dielectric layers. A thinner first dielectric layer is adjacent the gate edge at the bottom of the gate electrode. The second dielectriclayer corresponds to the layer in the conventional structure, and it is level with the main portion of the gate foot.

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 method of manufacturing a semiconductor device includes the steps of forming a gate electrode of a transistor on an insulator layer on a surface of a semiconductor substrate, forming an isolation region by performing ion implantation of an impurity of a first conductivity type into the semiconductor substrate, forming a lightly doped drain region by performing, after forming a mask pattern including an opening portion narrower than a width of the gate electrode on an upper layer of the gate electrode of the transistor, ion implantation of an impurity of a second conductivity type near the surface of the semiconductor substrate with the mask pattern as a mask, and forming a source region and a drain region of the transistor by performing ion implantation of an impurity of the second conductivity type into the semiconductor substrate after forming the gate electrode of the transistor.

Abstract: The present invention may provide an integrated device, which may include a substrate having first and second regions, the first region spaced apart from the second region, a first heterojunction bipolar transistor (HBT) device formed on the first region of the substrate, the first HBT device having a first collector layer formed above the first region of the substrate, the first collector layer having a first collector thickness and a first collector doping level, and a second HBT device formed on the second region of the substrate, the second HBT device having a second collector layer formed above the second region of the substrate, the second collector layer having a second collector thickness and a second collector doping level, the second collector thickness substantially greater than the first collector thickness, the second collector doping level lower than the first collector doping level.

Abstract: An AlGaN/GaN HEMT includes a compound semiconductor laminated structure, a gate electrode formed above the compound semiconductor laminated structure, and a p-type semiconductor layer formed between the compound semiconductor laminated structure and the gate electrode, and the p-type semiconductor layer has tensile strain in a direction parallel to a surface of the compound semiconductor laminated structure.

Abstract: A heterojunction bipolar transistor (HBT), an integrated circuit (IC) chip including at least one HBT and a method of forming the IC. The HBT includes an extrinsic base with one or more buried interstitial barrier layer. The extrinsic base may be heavily doped with boron and each buried interstitial barrier layer is doped with a dopant containing carbon, e.g., carbon or SiGe:C. The surface of the extrinsic base may be silicided.

Abstract: The present invention provides a method of forming a transistor. The method includes forming a first layer of a first semiconductor material above an insulation layer. The first semiconductor material is selected to provide high mobility to a first carrier type. The method also includes forming a second layer of a second semiconductor material above the first layer of semiconductor material. The second semiconductor material is selected to provide high mobility to a second carrier type opposite the first carrier type. The method further includes forming a first masking layer adjacent the second layer and etching the second layer through the first masking layer to form at least one feature in the second layer. Each feature in the second layer forms an inverted-T shape with a portion of the second layer.

Abstract: Some exemplary embodiments of high voltage cascoded III-nitride semiconductor package utilizing clips on a package support surface have been disclosed. One exemplary embodiment comprises a III-nitride transistor attached to a package support surface and having an anode of a diode stacked over a source of the III-nitride transistor, a first conductive clip coupled to a gate of the III-nitride transistor and the anode of the diode, and a second conductive clip coupled to a drain of the III-nitride transistor. The conductive clips are connected to the package support surface and expose respective flat portions that are surface mountable. In this manner, reduced package footprint, improved surge current capability, and higher performance may be achieved compared to conventional wire bonded packages. Furthermore, since a low cost printed circuit board (PCB) may be utilized for the package support surface, expensive leadless fabrication processes may be avoided for cost effective manufacturing.

Abstract: A high-speed SiGe HBT is disclosed, which includes: a substrate; STIs formed in the substrate; a collector region formed beneath the substrate surface and located between the STIs; an epitaxial dielectric layer including two portions, one being located on the collector region, the other being located on one of the STIs; a base region formed both in a region between and on surfaces of the two portions of the epitaxial dielectric layer; an emitter dielectric layer including two portions, both portions being formed on the base region; an emitter region formed both in a region between and on surfaces of the two portions of the emitter dielectric layer; a contact hole formed on a surface of each of the base region, the emitter region and the collector region. A method of manufacturing high-speed SiGe HBT is also disclosed.

Abstract: A wafer comprising at least one emitter-up Heterojunction Bipolar Transistor (HBT) and at least one emitter-down HBT on a common InP based semiconductor wafer. Isolation and N-type implants into the device layers differentiate an emitter-down HBT from an emitter-up HBT. The method for preparing a device comprises forming identical layers for all HBTs and performing ion implantation to differentiate an emitter-down HBT from an emitter-up HBT.

Abstract: An active device, a driving circuit structure, and a display panel are provided. The active device includes a gate, a gate insulation layer covering the gate, a semiconductor layer disposed above the gate, an etching stop layer disposed on the gate insulation layer and the semiconductor layer, a source, and a drain. The gate forms a meandering pattern on a substrate. The semiconductor layer has an area substantially defining a device region where the active device is. The etching stop layer has a first contact opening and a second contact opening. The first contact opening and the second contact opening separated from each other and both exposing the semiconductor layer. The source and the drain separated from each other are disposed on the etching stop layer and in contact with the semiconductor layer through the first contact opening and the second contact opening, respectively.

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: Embodiments of the present invention include a method for forming a tunable semiconductor device. In one embodiment, the method comprises: forming a semiconductor substrate; patterning a first mask over the semiconductor substrate; doping regions of the semiconductor substrate not protected by the first mask to form a first discontinuous subcollector; removing the first mask; patterning a second mask over the semiconductor substrate; doping regions of the semiconductor substrate not protected by the second mask and on top of the first discontinuous subcollector to form a second discontinuous subcollector; removing the second mask; and forming a single continuous collector above the second discontinuous subcollector.

Abstract: A heterojunction bipolar transistor (HBT) with improved current gain and the fabrication method thereof, in which the HBT comprises a substrate, a p-type buffer layer, a sub-collector layer, a collector layer, a base layer, an emitter layer, an emitter cap layer, and an emitter contact layer. Multiple etching processes are used for etching a base electrode contact region and terminated at the base layer. A collector electrode contact region is then formed in the base electrode contact region by an etching process terminated at the sub-collector layer. A base electrode is disposed on the base layer in the base electrode contact region. A collector electrode is disposed on the sub-collector layer in the collector electrode contact region. An emitter electrode is disposed on the emitter layer.

Abstract: The present invention discloses a metal silicide self-aligned SiGe heterojunction bipolar transistor, which is designed to overcome the shortcomings such as the large base resistance RB of the prior art products. The metal silicide self-aligned SiGe heterojunction bipolar transistor of the present invention mainly comprises an Si collector region, a local dielectric region, a base region, a base-region low-resistance metal silicide layer, a polysilicon emitter region, an emitter-base spacer dielectric region composed of a liner silicon oxide layer and a silicon nitride inner sidewall, a monocrystalline emitter region, a contact hole dielectric layer, an emitter metal electrode and a base metal electrode. The base-region low-resistance metal silicide layer extends all the way to the outside of the emitter-base spacer dielectric region. The present invention discloses a method of forming a metal silicide self-aligned SiGe heterojunction bipolar transistor, which is used to form the aforesaid bipolar transistor.

Abstract: A heterojunction bipolar transistor is formed with an emitter electrode that comprises an emitter epitaxy underlying an emitter metal cap and that has horizontal dimensions that are substantially equal to the emitter metal cap.

Abstract: A combinationally doped semiconductor layer, a double heterojunction bipolar transistor (DHBT) including a combinationally doped semiconductor layer, and a method of making a combinationally doped semiconductor layer employ a combination of carbon and beryllium doping. The combinationally doped semiconductor layer includes a first sublayer of a semiconductor material doped substantially with beryllium and a second sublayer of the semiconductor material doped substantially with carbon. The DHBT includes a carbon-beryllium combinationally doped semiconductor layer as a base layer. The method of making a combinationally doped semiconductor layer includes growing a first sublayer of the semiconductor layer, the first sublayer being doped substantially with beryllium and growing a second sublayer of the semiconductor layer, the second sublayer being doped substantially with carbon.

Abstract: A lateral heterojunction bipolar transistor is formed on a semiconductor-on-insulator substrate including a top semiconductor portion of a first semiconductor material having a first band gap and a doping of a first conductivity type. A stack of an extrinsic base and a base cap is formed such that the stack straddles over the top semiconductor portion. A dielectric spacer is formed around the stack. Ion implantation of dopants of a second conductivity type is performed to dope regions of the top semiconductor portion that are not masked by the stack and the dielectric spacer, thereby forming an emitter region and a collector region. A second semiconductor material having a second band gap greater than the first band gap and having a doping of the second conductivity type is selectively deposited on the emitter region and the collector region to form an emitter contact region and a collector contact region, respectively.

Abstract: A switching device for heterojunction integrated circuits is disclosed. According to one aspect, the switching device is configured to protect a circuit from an electro-static discharge (ESD) event. The switching device includes a second base contact region that is configured to be electrically floating, a first base contact region and a collector contact region that are coupled to a first input terminal of the switching device, and an emitter contact region that is coupled to a second input terminal of the switching device. Due in part to capacitive coupling between the first base contact region and the second base contact region, the switching device exhibits a low transient trigger voltage and a fast response to ESD events. Further, the switching device exhibits a high DC trigger voltage (for example, greater than 20V), while maintaining relatively low leakage current during operation (for example, less than about 0.5 ?A at 20V DC.

Abstract: A method for pseudomorphic growth and integration of an in-situ doped, strain-compensated metastable compound base into an electronic device, such as, for example, a SiGe NPN HBT, by substitutional placement of strain-compensating atomic species. The invention also applies to strained layers in other electronic devices such as strained SiGe, Si in MOS applications, vertical thin film transistors (VTFT), and a variety of other electronic device types. Devices formed from compound semiconductors other than SiGe, such as, for example, GaAs, InP, and AlGaAs are also amenable to beneficial processes described herein.

Abstract: A method of forming a heterojunction bipolar transistor by depositing a first stack comprising an polysilicon layer and a sacrificial layer on a mono-crystalline silicon substrate surface; patterning that stack to form a trench extending to the substrate; depositing a silicon layer over the resultant structure; depositing a silicon-germanium-carbon layer over the resultant structure; selectively removing the silicon-germanium-carbon layer from the sidewalls of the trench; depositing a boron-doped silicon-germanium-carbon layer over the resultant structure; depositing a further silicon-germanium-carbon layer over the resultant structure; depositing a boron-doped further silicon layer over the resultant structure; forming dielectric spacers on the trench sidewalls; filling the trench with emitter material; exposing polysilicon regions outside the trench side walls by selectively removing the sacrificial layer; implanting boron impurities into the exposed polysilicon regions to define base implants; and exposing

Abstract: Disclosed are a transistor (e.g., bipolar junction transistor (BJT) or a heterojunction bipolar transistor (HBT)) and a method of forming the transistor with a narrow in-substrate collector region for reduced base-collector junction capacitance. The transistor has, within a substrate, a collector region positioned laterally adjacent to a trench isolation region. A relatively thin seed layer covers the trench isolation region and collector region. This seed layer has a monocrystalline center, which is aligned above and wider than the collector region (e.g., due to a solid phase epitaxy regrowth process), and a polycrystalline outer section. An intrinsic base layer is epitaxially deposited on the seed layer such that it similarly has a monocrystalline center section that is aligned above and wider than the collector region. An extrinsic base layer is the intrinsic base layer and has a monocrystalline extrinsic base-to-intrinsic base link-up region that is offset vertically from the collector region.

Abstract: A semiconductor device includes a substrate, a carrier transit layer disposed above the substrate, a compound semiconductor layer disposed on the carrier transit layer, a source electrode disposed on the compound semiconductor layer, a first groove disposed from the back of the substrate up to the inside of the carrier transit layer while penetrating the substrate, a drain electrode disposed in the inside of the first groove, a gate electrode located between the source electrode and the first groove and disposed on the compound semiconductor layer, and a second groove located diagonally under the source electrode and between the source electrode and the first groove and disposed from the back of the substrate up to the inside of the carrier transit layer while penetrating the substrate.

Abstract: A heterojunction bipolar transistor (HBT) structure, method of manufacturing the same and design structure thereof are provided. The HBT structure includes a semiconductor substrate having a sub-collector region therein. The HBT structure further includes a collector region overlying a portion of the sub-collector region. The HBT structure further includes an intrinsic base layer overlying at least a portion of the collector region. The HBT structure further includes an extrinsic base layer adjacent to and electrically connected to the intrinsic base layer. The HBT structure further includes an isolation region extending vertically between the extrinsic base layer and the sub-collector region. The HBT structure further includes an emitter overlying a portion of the intrinsic base layer. The HBT structure further includes a collector contact electrically connected to the sub-collector region. The collector contact advantageously extends through at least a portion of the extrinsic base layer.

Abstract: A power SiGe heterojunction bipolor transistor (HBT) with improved drive current by strain compensation and methods of manufacture are provided. A method includes adding carbon in a continuous steady concentration in layers of a device including a subcollector layer, a collector layer, a base buffer layer, a base layer, and an emitter buffer layer.

Abstract: A self-aligned bipolar transistor and method of fabricating the same are disclosed. In an embodiment, a substrate and an intrinsic base are provided, followed by a first oxide layer, and an extrinsic base over the first oxide layer. A first opening is formed, exposing a portion of a surface of the extrinsic base. Sidewall spacers are formed in the first opening, and a self-aligned oxide mask is selectively formed on the exposed surface of the extrinsic base. The spacers are removed, and using the self-aligned oxide mask, the exposed extrinsic base and the first oxide layer are etched to expose the intrinsic base layer, forming a first and a second slot. A silicon layer stripe is selectively grown on the exposed intrinsic and/or extrinsic base layers in each of the first and second slots, substantially filling the respective slot.

Abstract: Disclosed are a transistor and a method of forming the transistor with a raised collector pedestal in reduced dimension for reduced base-collector junction capacitance. The raised collector pedestal is on the top surface of a substrate, extends vertically through dielectric layer(s), is un-doped or low-doped, is aligned above a sub-collector region contained within the substrate and is narrower than that sub-collector region. An intrinsic base layer is above the raised collector pedestal and the dielectric layer(s). An extrinsic base layer is above the intrinsic base layer. Thus, the space between the extrinsic base layer and the sub-collector region is increased. This increased space is filled by dielectric material and the electrical connection between the intrinsic base layer and the sub-collector region is provided by the relatively narrow, un-doped or low-doped, raised collector pedestal.

Abstract: A method for fabricating a semiconductor device having a first and second bipolar devices of the same dopant type includes: depositing a dielectric layer over a semiconductor layer, depositing a gate conductor layer over the dielectric layer, defining base regions of both bipolar devices, removing the gate conductor layer and dielectric layer in the base regions, depositing a base layer on the gate conductor layer and on the exposed semiconductor layer in the base regions, depositing an insulating layer over the base layer, forming a photoresist layer and defining emitter regions of both bipolar devices, removing the photoresist layer in the emitter regions thereby forming two emitter windows, masking the emitter window of the first bipolar device and exposing the base layer in the base region of the second bipolar device to an additional emitter implant through the associated emitter window.

Abstract: A heterojunction bipolar transistor (HBT) may include an n-type doped crystalline collector formed in an upper portion of a crystalline silicon substrate layer; a p-type doped crystalline p+Si1-xGex layer, formed above the n-type doped collector, that forms a p-type doped internal base of the HBT; a crystalline silicon cap formed on the p-type doped crystalline p+Si1-xGex layer, in which the crystalline silicon cap includes an n-type impurity and forms an n-type doped emitter of the HBT; and an n-type doped crystalline silicon emitter stack formed within an opening through an insulating layer to an upper surface of the crystalline silicon cap.

Abstract: Disclosed are embodiments of a transistor (e.g., bipolar junction transistor (BJT) or a heterojunction bipolar transistor (HBT)) and a method of forming the transistor with a collector region having a protected upper edge portion for reduced base-collector junction capacitance Cbc. In the embodiments, a collector region is positioned laterally adjacent to a trench isolation region within a substrate. Mask layer(s) cover the trench isolation region and further extend laterally onto the edge portion of the collector region. A first section of an intrinsic base layer is positioned above a center portion of the collector region and a second section of the intrinsic base layer is positioned above the mask layer(s). During processing these mask layer(s) prevent divot formation in the upper corner of the trench isolation region at the isolation region-collector region interface and further limit dopant diffusion from a subsequently formed raised extrinsic base layer into the collector region.

Abstract: Methods of fabricating bipolar junction transistors, bipolar junction transistors, and design structures for a bipolar junction transistor. A first portion of the intrinsic base layer is masked while a second portion of an intrinsic base layer is etched. As a consequence of the masking, the second portion of the intrinsic base layer is thinner than the first portion of the intrinsic base layer. An emitter and an extrinsic base layer are formed in respective contacting relationships with the first and second portions of the intrinsic base layer.

Abstract: A silicon-germanium (SiGe) heterojunction bipolar transistor (HBT) having a deep pseudo buried layer is disclosed. The SiGe HBT includes isolation structures formed in trenches, first pseudo buried layers and second pseudo buried layers, and a collector region. The first pseudo buried layers are formed under the respective trenches and the second pseudo buried layers are formed under the first pseudo buried layers, with each first pseudo buried layer vertically contacting with a second pseudo buried layer. The second pseudo buried layers are laterally connected to each other, and the collector region is surrounded by the trenches, the first pseudo buried layers and the second pseudo buried layers. The cross section of each of the trenches has a regular trapezoidal shape, namely, each trench's width of its top is smaller than that of its bottom. A manufacturing method of the SiGe HBT is also disclosed.

Abstract: A silicon-germanium (SiGe) heterojunction bipolar transistor (HBT) is disclosed, which includes: two isolation structures each being formed in a trench; a set of three or more pseudo buried layers formed under each trench with every adjacent two pseudo buried layers of the set being vertically contacted with each other; and a collector region. In this design, the lowermost pseudo buried layers of the two sets are laterally in contact with each other, and the collector region is surrounded by the two isolation structures and the two sets of pseudo buried layers. As the breakdown voltage of a SiGe HBT according to the present invention is determined by the distance between an uppermost pseudo buried layer and the edge of an active region, SiGe HBTs having different breakdown voltages can be achieved. A manufacturing method of the SiGe HBT is also disclosed.

Abstract: A SiGe HBT is disclosed, which includes: a silicon substrate; shallow trench field oxides formed in the silicon substrate; a pseudo buried layer formed at bottom of each shallow trench field oxide; a collector region formed beneath the surface of the silicon substrate, the collector region being sandwiched between the shallow trench field oxides and between the pseudo buried layers; a polysilicon gate formed above each shallow trench field oxide having a thickness of greater than 150 nm; a base region on the polysilicon gates and the collector region; emitter region isolation oxides on the base region; and an emitter region on the emitter region isolation oxides and a part of the base region. The polysilicon gate is formed by gate polysilicon process of a MOSFET in a CMOS process. A method of manufacturing the SiGe HBT is also disclosed.

Abstract: Embodiments of semiconductor structure are disclosed along with methods of forming the semiconductor structure. In one embodiment, the semiconductor structure includes a semiconductor substrate, a collector layer formed over the semiconductor substrate, a base layer formed over the semiconductor substrate, and an emitter layer formed over the semiconductor substrate. The semiconductor substrate is formed from Gallium Arsenide (GaAs), while the base layer is formed from a Gallium Indium Nitride Arsenide Antimonide (GaInNAsSb) compound. The base layer formed from the GaInNAsSb compound has a low bandgap, but a lattice that substantially matches a lattice constant of the underlying semiconductor substrate formed from GaAs. In this manner, semiconductor devices with lower base resistances, turn-on voltages, and/or offset voltages can be formed using the semiconductor structure.

Abstract: A silicon-germanium (SiGe) heterojunction bipolar transistor (HBT) is disclosed, in which a shallow trench is formed of a first shallow trench and a second shallow trench vertically joined together in the active region, the second shallow trench being located directly under the first shallow trench and having a width less than that of the first shallow trench; a pseudo buried layer is formed surrounding the bottom and side walls of the second shallow trench and is in contact with the collector region to serve as a connection layer of a collector; a deep hole contact is formed in the shallow trench and is in contact with the pseudo buried layer to pick up the collector. A SiGe HBT manufacturing method is also disclosed. The present invention is capable of improving the cut-off frequency of a SiGe HBT.

Abstract: A method of manufacturing a semiconductor device includes the steps of forming a gate electrode of a transistor on an insulator layer on a surface of a semiconductor substrate, forming an isolation region by performing ion implantation of an impurity of a first conductivity type into the semiconductor substrate, forming a lightly doped drain region by performing, after forming a mask pattern including an opening portion narrower than a width of the gate electrode on an upper layer of the gate electrode of the transistor, ion implantation of an impurity of a second conductivity type near the surface of the semiconductor substrate with the mask pattern as a mask, and forming a source region and a drain region of the transistor by performing ion implantation of an impurity of the second conductivity type into the semiconductor substrate after forming the gate electrode of the transistor.