Abstract: A first (e.g. replaceable or disposable) dielectric spacer formed on a sidewall of a dummy emitter mandrel is removed after a raised extrinsic base layer and covering dielectric layer are formed. Thereafter, a second dielectric spacer is formed within the opening that results. As a result, the second dielectric spacer, which is not subjected to RIE processing, provides a desired level of isolation and tighter emitter final critical dimension than that which could be achieved through the technique described in the prior art. In a particular embodiment, an additional layer of silicon nitride is disposed over a passivation oxide layer as a sacrificial layer which protects the passivation oxide layer from being reduced in thickness and/or being undercut during the RIE process and one or more cleaning processes conducted after the RIE process.

Abstract: The invention provides an electrostatic discharge (ESD) protection device having an ESD path between a first circuit and a second circuit. The electrostatic discharge protection device includes a first doped region having a first conductive type. A first well has a second conductive type opposite to the first conductive type. A second doped region and a third doped region are in the first well, respectively having the first and second conductive types. The first doped region is coupled to a power supply terminal or a ground terminal of the first circuit, and the second and third doped regions are both coupled to a power supply terminal or a ground terminal of the second circuit, respectively.

Abstract: A method for integrating a bipolar injunction transistor in a semiconductor chip includes the steps of forming an intrinsic base region of a second type of conductivity extending in the collector region from a main surface through an intrinsic base window of the sacrificial insulating layer, forming an emitter region of the first type of conductivity extending in the intrinsic base region from the main surface through an emitter window of the sacrificial insulating layer, removing the sacrificial insulating layer, forming an intermediate insulating layer on the main surface, and forming an extrinsic base region of the second type of conductivity extending in the intrinsic base region from the main surface through an extrinsic base window of the intermediate insulating layer

Abstract: Bipolar transistors with tailored response curves, as well as fabrication methods for bipolar transistors and design structures for BiCMOS integrated circuits. The bipolar transistor includes a first section of a collector region implanted with a first dopant concentration and a second section of the collector region implanted with a second dopant concentration that is higher than the first dopant concentration. A first emitter is formed in vertical alignment with the first section of the collector region. A second emitter is formed in vertical alignment with the second section of the collector region.

Abstract: A power supply device is disclosed that is able to satisfy the power requirements of a device in service and has high efficiency. The power supply device includes a first power supply; a voltage step-up unit that steps up an output voltage of the first power supply; a voltage step-down unit that steps down an output voltage of the voltage step-up unit; and a load that is driven to operate by an output voltage of the voltage step-down unit. The voltage step-up unit steps up the output voltage of the first power supply to a lower limit of an operating voltage of the voltage step-down unit.

Abstract: According to an embodiment, a method for manufacturing a semiconductor device is provided. The method includes providing a mask layer which is used as an implantation mask when forming a doping region and which is used as an etching mask when forming an opening and a contact element formed in the opening. The contact element is in contact with the doping region.

Abstract: A SiGe heterojunction bipolar transistor is fabricated by etching an epitaxially-formed structure to form a mesa that has a collector region, a cap region, and a notched SiGe base region that lies in between. A protective plug is formed in the notch of the SiGe base region so that thick non-conductive regions can be formed on the sides of the collector region and the cap region. Once the non-conductive regions have been formed, the protective plug is removed. An extrinsic base is then formed to lie in the notch and touch the base region, followed by the formation of isolation regions and an emitter region.

Abstract: A transistor capable of modulating, at low voltages, a large current flowing between an emitter electrode and a collector electrode. A process of producing the transistor, a light-emitting device comprising the transistor, and a display comprising the transistor. The transistor comprises an emitter electrode and a collector electrode. Between the emitter electrode and the collector electrode are situated a semiconductor layer and a sheet base electrode. It is preferred that the semiconductor layer be situated between the emitter electrode and the base electrode and also between the collector electrode and the base electrode to constitute a second semiconductor layer and a first semiconductor layer, respectively. It is also preferred that the thickness of the base electrode be 80 nm or less. Furthermore, a dark current suppressor layer is situated at least between the emitter electrode and the base electrode, or between the collector electrode and the base electrode.

Abstract: Preferred embodiment flexible and on wafer hybrid plasma semiconductor devices have at least one active solid state semiconductor region; and a plasma generated in proximity to the active solid state semiconductor region(s). Doped solid state semiconductor regions are in a thin flexible solid state substrate, and a flexible non conducting material defining a microcavity adjacent the semiconductor regions. The flexible non conducting material is bonded to the thin flexible solid state substrate, and at least one electrode is arranged with respect to said flexible substrate to generate a plasma in said microcavity, where the plasma will influence or perform a semiconducting function in cooperation with said solid state semiconductor regions. A preferred on-wafer device is formed on a single side of a silicon on insulator wafer and defines the collector (plasma cavity), emitter and base regions on a common side, which provides a simplified and easy to manufacture structure.

Abstract: A bipolar transistor comprises at least first and second connected emitter-base (EB) junctions having, respectively, different first and second EB junction depths, and a buried layer (BL) collector having a greater third depth. The emitters and bases corresponding to the different EB junctions are provided during a chain implant. An isolation region overlies the second EB junction location thereby providing its shallower EB junction depth. The BL collector does not underlie the first EB junction and is laterally spaced therefrom by a variable amount to facilitate adjusting the transistor's properties. In other embodiments, the BL collector can underlie at least a portion of the second EB junction. Regions of opposite conductivity type over-lie and under-lie the BL collector, which is relatively lightly doped, thereby preserving the breakdown voltage. The transistor can be readily “tuned” by mask adjustments alone to meet various device requirements.

Abstract: Instability and drift sometimes observed in bipolar transistors, having a portion of the base extending to the transistor surface between the emitter and base contact, can be reduced or eliminated by providing a further doped region of the same conductivity type as the emitter at the transistor surface between the emitter and the base contact. The further region is desirably more heavily doped than the base region at the surface and less heavily doped than the adjacent emitter. In another embodiment, a still or yet further region of the same conductivity type as the emitter is provided either between the further region and the emitter or laterally within the emitter. The still or yet further region is desirably more heavily doped than the further region. Such further regions shield the near surface base region from trapped charge that may be present in dielectric layers or interfaces overlying the transistor surface.

Abstract: To provide a semiconductor device in which an interval between first wells can be shortened by improving a separation breakdown voltage between the first wells and a method for manufacturing the same.

Abstract: In accordance with an embodiment of the present invention a transistor is disclosed. The transistor comprises a collector, a base and an emitter, wherein a first end width of the base is larger than a middle width of the base, wherein a first end width of the collector is larger than a middle width of the collector, or wherein a first end width of the emitter is larger than a middle width of the emitter.

Abstract: A bipolar junction transistor includes a semiconductor island on an insulating substrate; an emitter and at least one of a collector and sub collector within the semiconductor island, the emitter and the at least one of the collector and the sub collector being of a first conductivity type; a base within the semiconductor island separating the emitter and the at least one of the collector and the sub collector, the base being of a second conductivity type; a base contact region within the semiconductor island, the base contact region being of the second conductivity type; and a connecting base region adjacent the base within the semiconductor island and connecting the base to the base contact region while not directly contacting the emitter, the connecting base region being of the second conductivity type with a doping concentration less than a doping concentration of the base contact region.

Abstract: The present disclosure provides a bipolar junction transistor (BJT) device and methods for manufacturing the BJT device. In an embodiment, the BJT device includes: a semiconductor substrate having a collector region, and a material layer disposed over the semiconductor layer. The material layer has a trench therein that exposes a portion of the collector region. A base structure, spacers, and emitter structure are disposed within the trench of the material layer. Each spacer has a top width and a bottom width, the top width being substantially equal to the bottom width.

Abstract: In the case of adjacent high voltage nodes in which one node is protected by a lateral BJT clamp, the irreversible burnout due to transient latch-up between the two adjacent high voltage pins of the structure is avoided by increasing the base contact region by including a sinker connected to the base.

Abstract: A parasitic PIN device in a BiCMOS process is disclosed. The device is formed on a silicon substrate, in which an active region is isolated by shallow trenches. The device includes: an N-type region, consisting of N-type pseudo buried layers respectively formed at the bottom of shallow trench isolation oxide layers and extending into the active region; an I-type region, consisting of an N-type collector implantation region formed in the active region and contacting with the N-type region; a P-type region, consisting of a P-doped intrinsic base epitaxial layer on a surface of the active region and contacting with the I-type region. The device of the present invention has a low insertion loss and a high isolation. A manufacturing method of parasitic PIN device in compatible with existing BiCMOS process is also disclosed.

Abstract: The present invention relates to semiconductor technologies, and more particularly to a bipolar junction transistor (BJT) in a CMOS base technology and methods of forming the same. The BJT includes a semiconductor substrate having an emitter region, a base having a first contact, and a collector having a second contact and a well plug; a first silicide film on the first contact; a second silicide film on the second contact; a first silicide blocking layer on or over the semiconductor substrate between the first and second silicide films, and a second silicide blocking layer on the semiconductor substrate between the first silicide film and the emitter region.

Abstract: A bipolar junction transistor (BJT) device including a base region, an emitter region and a collector region comprises a substrate, a deep well region in the substrate, a first well region in the deep well region to serve as the base region, a second well region in the deep well region to serve as the collector region, the second well region and the first well region forming a first junction therebetween, and a first doped region in the first well region to serve as the emitter region, the first doped region and the first well region forming a second junction therebetween, wherein the first doped region includes a first section extending in a first direction and a second section extending in a second direction different from the first direction, the first section and the second section being coupled with each other.

Abstract: The invention, in one aspect, provides a semiconductor device that comprises a collector located in a semiconductor substrate and an isolation region located under the collector, wherein a peak dopant concentration of the isolation region is separated from a peak dopant concentration of the collector that ranges from about 0.9 microns to about 2.0 microns.

Abstract: A bipolar semiconductor component, in particular a diode, comprising an anode structure which controls its emitter efficiency in a manner dependent on the current density in such a way that the emitter efficiency is low at small current densities and sufficiently high at large current densities, and an optional cathode structure, which can inject additional holes during commutation, and production methods therefor.

Abstract: Memory devices and methods for manufacturing are described herein. A memory device described herein includes a plurality of memory cells. Memory cells in the plurality of memory cells comprise respective bipolar junction transistors and memory elements. The bipolar junction transistors are arranged in a common collector configuration and include an emitter comprising doped polysilicon having a first conductivity type, the emitter contacting a corresponding word line in a plurality of word lines to define a pn junction. The bipolar junction transistors include a portion of the corresponding word line underlying the emitter acting as a base, and a collector comprising a portion of the single-crystalline substrate underlying the base.

Abstract: The present disclosure relates to a silicon carbide (SiC) bipolar junction transistor (BJT), where the surface region between the emitter and base contacts (1, 2) on the transistor is given a negative electric surface potential with respect to the potential in the bulk SiC. The present disclosure also relates to a method for increasing the current gain in a silicon carbide (SiC) bipolar junction transistor (BJT) by the reduction of the surface recombination at the SiC surface between the emitter and base contacts (1, 2) of the transistor.

Abstract: A semiconductor device provided with: an island and an island which are separated from each other; leads which approach the islands at one end; a control element which is attached to the island and is connected to a lead through a thin metal wire; and a switching element which is attached to the island and is connected to the lead through a metal wire. Further, the thin metal wire and the thin metal wire are arranged so as to the intersect.

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

Abstract: Methods for manufacturing a bipolar transistor semiconductor device are described, along with devices fabricated in accordance with the methods. The methods include the steps of forming a stack of layers over a semiconductor body comprising a window definition layer (18,38), a layer (20) of semiconductor material, a first insulating layer (22), and a second insulating layer (24) which is selectively etchable with respect to the first insulating layer. A trench (26) is then etched into the stack down to the window definition layer. The portion of the trench extending through the second insulating layer is widened to form a wider trench portion (28) therethrough. A window (36) is defined in the window definition layer which is aligned with the wider trench portion, and serves to define the base-collector or base-emitter junction in the finished device.

Abstract: The disclosed invention provides a method for the fabrication of a bipolar transistor having a collector region comprised within a semiconductor body separated from an overlying base region by one or more isolation cavities (e.g., air gaps) filled with low permittivity gas. In particular, a multilayer base-collector dielectric film is deposited over the collector region. A base region is formed onto the multilayer dielectric film and is patterned to form one or more base connection regions. The multilayer dielectric film is selectively etched during a plurality of isotropic etch processes to allow for the formation of one or more isolation region between the base connection regions and the collector region, wherein the one or more isolation regions comprise cavities filled with a gas having a low dielectric constant (e.g., air). The resultant bipolar transistor has a reduced base-collector capacitance, thereby allowing for improved frequency properties (e.g., higher maximum frequency operation).

Abstract: The invention, in one aspect, provides a semiconductor device that includes a collector for a bipolar transistor located within a semiconductor substrate and a buried contact, at least a portion of which is located in the collector to a depth sufficient that adequately contacts the collector.

Abstract: A bipolar junction transistor having a carrier trapping layer, comprises a semi-conductor substrate including a well with a first type ions formed thereon; two impurity regions with a second type ions formed opposite with each other over the well; an insulation layer over the well, and edges extend over the second two impurity regions; and a carrier trapping layer formed over the insulation layer.

Abstract: An ESD protection device comprises a substrate of a first conductive type; a transistor formed in the substrate having an input terminal of the first conductive type, a control terminal of a second conductive type, and a ground terminal of the first conductive type; and a diode formed in the substrate having a first terminal of the first conductive type and a second terminal of the second conductive type, wherein the input terminal and the second terminal are coupled to an input, and the ground terminal and the first terminal are coupled to a ground.

Abstract: A semiconductor integrated circuit includes: a substrate of a first conductivity type; a first diffusion layer of a second conductivity type formed on the substrate; a second diffusion layer of the first conductivity type formed in an upper part of the first diffusion layer; a third diffusion layer of the second conductivity type formed in an upper part of the second diffusion layer; a fourth diffusion layer of the second conductivity type formed in the upper part of the first diffusion layer; and a fifth diffusion layer of the first conductivity type formed below the third diffusion layer. A sum of a shortest distance from the third diffusion layer to the fifth diffusion layer and a shortest distance from the fifth diffusion layer or the lower end of the first diffusion layer to the fourth diffusion layer is smaller than a shortest distance from the third diffusion layer to the fourth diffusion layer.

Abstract: Memory devices and methods for manufacturing are described herein. A memory device described herein includes a plurality of memory cells. Memory cells in the plurality of memory cells comprise respective bipolar junction transistors and memory elements. The bipolar junction transistors are arranged in a common collector configuration and include an emitter comprising doped polysilicon having a first conductivity type, the emitter contacting a corresponding word line in a plurality of word lines to define a pn junction. The bipolar junction transistors include a portion of the corresponding word line underlying the emitter acting as a base, and a collector comprising a portion of the single-crystalline substrate underlying the base.

Abstract: The present invention provides a technology that makes it possible to enhance the gain and the efficiency of an RF bipolar transistor. Device isolation is given between a p+ type isolation region and an n+ type collector embedded region and between a p+ type isolation region and an n type collector region (an n+ type collector extraction region) with an isolation section that surrounds the collector extraction region in a plan view and is formed by embedding a dielectric film in a groove penetrating an isolation section, a collector region, and a collector embedded region and reaching a substrate. Further, a current route is formed between an emitter wiring (a wiring) and the substrate with an electrically conductive layer formed by embedding the electrically conductive layer in a groove penetrating a dielectric film, silicon oxide films, a semiconductor region, and the isolation regions and reaching the substrate, and thereby the impedance between the emitter wiring and the substrate is reduced.

Abstract: A hydrogen ion sensing device includes: a reference electrode; a sensing portion which senses hydrogen ions by contacting an ion aqueous solution; and a plurality of ring-like lateral bipolar junction transistors, each including a lateral collector, an emitter, a vertical collector and a floating gate connected to the reference electrode, with the emitter surrounded by the floating gate and the lateral collector, wherein the plurality of ring-like lateral bipolar junction transistors are formed on a common substrate and are connected in parallel. With this configuration, an operation point can be adjusted by the bases current with the emitter voltage fixed. In addition, polarities of values of X and Y axes are positive in comparison with a p-channel MOSFET driven with the common collector setting and the device can be operated in a linear region (an active mode) in comparison with ISFET operating in a saturation region.

Abstract: The first base electrodes and the first emitter electrodes are all formed like strips, and are alternately arranged in parallel, and the area of the second emitter electrode is expanded to be larger than that of the second base electrode. With this, the number of current paths increases in each of which a current is pulled up almost straight from the emitter region to the second emitter electrode through the first emitter electrodes, thereby preventing the current densities of the entire chip from becoming uneven.

Abstract: An ESD protection device is described, which includes a P-body region, a P-type doped region, an N-type doped region and an N-sinker region. The P-body region is configured in a substrate. The P-type doped region is configured in the middle of the P-body region. The N-type doped region is configured in the P-body region and surrounds the P-type doped region. The N-sinker region is configured in the substrate and surrounds the P-body region.

Abstract: According to one exemplary embodiment, a bipolar transistor includes a base having a top surface. The bipolar transistor further includes a base oxide layer situated on the top surface of the base. The bipolar transistor further includes an antireflective coating layer situated on the base oxide layer. The bipolar transistor further includes an emitter situated over the top surface of the base and the antireflective coating layer, where a layer of polysilicon is not situated between the base oxide layer and the emitter.

Abstract: A stackable electrostatic discharge (ESD) protection clamp (21) for protecting a circuit core (24) comprises, a bipolar transistor (56, 58) having a base region (74, 51, 52, 85) with a base contact (77) therein and an emitter (78) spaced a lateral distance Lbe from the base contact (77), and a collector (80, 86, 762) proximate the base region (74, 51, 52, 85). The base region (74, 51, 52, 85) comprises a first portion (51) including the base contact (77) and emitter (78), and a second portion (52) with a lateral boundary (752) separated from the collector (86, 762) by a breakdown region (84) whose width D controls the clamp trigger voltage, the second portion (52) lying between the first portion (51) and the boundary (752). The damage-onset threshold current It2 of the ESD clamp (21) is improved by increasing the parasitic resistance Rbe of the emitter-base region (74, 51, 52, 85), by for example, increasing Lbe or decreasing the relative doping density of the first portion (51) or a combination thereof.

Abstract: An electrostatic discharge (ESD) protection clamp (21, 21?, 70, 700) for protecting associated devices or circuits (24), comprises a bipolar transistors (21, 21?, 70, 700) in which doping of facing base (75) and collector (86) regions is arranged so that avalanche breakdown occurs preferentially within a portion (84, 85) of the base region (74, 75) of the device (70, 700) away from the overlying dielectric-semiconductor interface (791). Maximum variations (?Vt1)MAX of ESD triggering voltage Vt1 as a function of base-collector spacing dimensions D due, for example, to different azimuthal orientations of transistors (21, 21?, 70, 700) on a semiconductor die or wafer is much reduced. Triggering voltage consistency and manufacturing yield are improved.

Abstract: An NPN bipolar junction transistor is disclosed that exhibits a collector-to-emitter breakdown voltage greater than 10 volts and a beta greater than 300. The large value of beta is obtained by fabricating the transistor with an extra N-type layer that reduces recombination of electrons and holes.

Abstract: Carbon nanotube (CNT)-based devices and technology for their fabrication are disclosed. The planar, multiple layer deposition technique and simple methods of change of the nanotube conductivity type during the device processing are utilized to provide a simple and cost effective technology for large scale circuit integration. Such devices as p-n diode, CMOS-like circuit, bipolar transistor, light emitting diode and laser are disclosed, all of them are expected to have superior performance then their semiconductor-based counterparts due to excellent CNT electrical and optical properties. When fabricated on semiconductor wafers, the CNT-based devices can be combined with the conventional semiconductor circuit elements, thus producing hybrid devices and circuits.

Abstract: A semiconductor device is presented, which includes a semiconductor substrate with a high concentration impurity of a first type conductivity and an epitaxial layer with a low concentration impurity provided on the semiconductor substrate, where a trench coupled to the semiconductor substrate is provided in the epitaxial layer with the low concentration impurity. And the semiconductor device further includes a high concentration impurity region of the first type conductivity having the same type conductivity as the type of the semiconductor substrate formed in at least the epitaxial layer with the low concentration impurity along an inner wall of the trench and coupled to the semiconductor substrate with the high concentration impurity of a first type conductivity, and contacts formed on the high concentration impurity region of the first type conductivity.

Abstract: A high-frequency bipolar transistor includes an emitter contact adjoining an emitter connection region, a base contact adjoining a base connection region, and a collector contact adjoining a collector connection region. A first insulation layer is disposed on the base connection region. The collector connection region contains a buried layer, which connects the collector contact to a collector zone. A silicide or salicide region is provided on the buried layer and connects the collector contact to the collector zone in a low-impedance manner. A second insulation layer is disposed on the collector connection region but not on the silicide region.

Abstract: Semiconductor structures providing protection against electrostatic events of both polarities are provided. A pair of p-n junctions is provided underneath a shallow trench isolation portion between a first-conductivity-type well and each of a signal-side second-conductivity-type well and an electrical-ground-side second-conductivity-type well in a semiconductor substrate. A second-conductivity-type doped region and a first-conductivity-type doped region are formed above each second-conductivity-type well such that a portion of the second-conductivity-type well resistively separates the second-conductivity-type doped region and the first-conductivity-type doped region within the semiconductor substrate. Each of the second-conductivity-type doped regions is wired either to a signal node or electrical ground.

Abstract: A parasitic vertical PNP bipolar transistor in BiCMOS process comprises a collector, a base and an emitter. The collector is formed by active region with p-type ion implanting layer (P type well in NMOS). It connects a P-type conductive region, which formed in the bottom region of shallow trench isolation (STI). The collector terminal connection is through the P-type buried layer and the adjacent active region. The base is formed by N type ion implanting layer above the collector which shares a N-type lightly doped drain (NLDD) implanting of NMOS. Its connection is through the N-type poly on the base region. The emitter is formed by the P-type epitaxy layer on the base region with heavy p-type doped, and connected by the extrinsic base region of NPN bipolar transistor device. This invention also includes the fabrication method of this parasitic vertical PNP bipolar transistor in BiCMOS process.

Abstract: A bidirectional power transistor formed horizontally in a semiconductor layer disposed on a heavily-doped semiconductor wafer with an interposed insulating layer, the wafer being capable of being biased to a reference voltage, the product of the average dopant concentration and of the thickness of the semiconductor layer ranging between 5·1011 cm?2 and 5·1012 cm?2.

Abstract: An improved bipolar transistor (40, 40?) is provided, manufacturable by a CMOS IC process without added steps. The improved transistor (40, 40?) comprises an emitter (48) having first (482) and second (484) portions of different depths (4821, 4841), a base (46) underlying the emitter (48) having a central portion (462) of a first base width (4623) underlying the first portion (482) of the emitter (48), a peripheral portion (464) having a second base width (4643) larger than the first base width (4623) partly underlying the second portion (484) of the emitter (48), and a transition zone (466) of a third base width (4644) and lateral extent (4661) lying laterally between the first (462) and second (464) portions of the base (46), and a collector (44) underlying the base (46). The gain of the transistor (40, 40?) is much larger than a conventional bipolar transistor (20) made using the same CMOS process.

Abstract: A diode comprises a substrate formed of a first material having a first doping polarity. The substrate has a planar surface and at least one semispherical structure extending from the planar surface. The semispherical structure is formed of the first material. A layer of second material is over the semispherical structure. The second material comprises a second doping polarity opposite the first doping polarity. The layer of second material conforms to the shape of the semispherical structure. A first electrical contact is connected to the substrate, and a second electrical contact is connected to the layer of second material. Additional semiconductor structures are formed by fabricating additional layers over the original layers.

Abstract: Methods and structures for a semiconductor device can use mask openings of varying widths to form structures of different depths, different materials, and different functionality. For example, processes and structures for forming shallow trench isolation, deep isolation, trench capacitors, base, emitter, and collector, among other structures for a lateral bipolar transistor are described.

Abstract: The invention relates to a semiconductor device with a substrate and a semiconductor body of silicon comprising a bipolar transistor with an emitter region, a base region and a collector region which are respectively of the N-type conductivity, the P-type conductivity and the N-type conductivity by the provision of suitable doping atoms, wherein the base region comprises a mixed crystal of silicon and germanium, the base region is separated from the emitter region by an intermediate region of silicon having a doping concentration which is lower than the doping concentration of the emitter region and with a thickness smaller than the thickness of the emitter region, and the emitter region comprises a sub-region comprising a mixed crystal of silicon and germanium which is positioned at the side of emitter region remote from the intermediate region.