Abstract: A Bipolar Junction Transistor (BJT) includes an elongated collector line, an elongated emitter line parallel to the collector line, and an elongated base line parallel to the collector line and positioned between the collector line and the base line. The emitter line, the base line, and the collector line are formed over fin structures.

Abstract: An ESD transistor is provided. The ESD transistor includes a collector region on a substrate, a base contact region on the substrate, an emitter region spaced apart from the base contact region, a sink region disposed vertically below the collector region, and a buried layer disposed horizontally under the sink region.

Abstract: A Bipolar Junction Transistor with an intrinsic base, wherein the intrinsic base includes a top surface and two side walls orthogonal to the top surface, and a base contact electrically coupled to the side walls of the intrinsic base. In one embodiment an apparatus can include a plurality of Bipolar Junction Transistors, and a base contact electrically coupled to the side walls of the intrinsic bases of each BJT.

Abstract: Embodiments for forming improved bipolar transistors are provided, manufacturable by a CMOS IC process. The improved transistor comprises an emitter having first and second portions of different depths, a base underlying the emitter having a central portion of a first base width underlying the first portion of the emitter, a peripheral portion having a second base width larger than the first base width partly underlying the second portion of the emitter, and a transition zone of a third base width and lateral extent lying laterally between the first and second portions of the base, and a collector underlying the base. The gain of the transistor is larger than a conventional bipolar transistor made using the same CMOS process. By adjusting the lateral extent of the transition zone, the properties of the improved transistor can be tailored to suit different applications without modifying the underlying CMOS IC process.

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 is disclosed for forming vertical bipolar junction transistors including a regular array of base contact pillars and emitter contact pillars with a width below the minimum lithographical resolution F of the lithographic technique employed. In an embodiment, the pillar array features have a dimension of approximately F/2, though this dimension could be reduced down to other values compatible with embodiments of the invention. A storage element, such as a phase change storage element, can be formed above the regular array of base contact pillars and emitter contact pillars.

Abstract: Methods for fabricating bipolar junction transistors, bipolar junction transistors, and design structures for a bipolar junction transistor. The bipolar junction transistor may include a plurality of emitters that are arranged in distinct emitter fingers. A silicide layer is formed that covers an extrinsic base layer of the bipolar junction transistor and that fills the gaps between adjacent emitters. Non-conductive spacers on the emitter sidewalls electrically insulate the emitters from the silicide layer. The emitters extend through the extrinsic base layer and the silicide layer to contact the intrinsic base layer. The emitters may be formed using sacrificial emitter pedestals in a replacement-type process.

Abstract: Integrated circuits (ICs) utilize bipolar transistors in electro-static discharge (ESD) protection circuits to shunt discharge currents during ESD events to protect the components in the ICs. Bipolar transistors are subject to non-uniform current crowding across the emitter-base junction during ESD events, which results in less protection for the IC components and degradation of the bipolar transistor. This invention comprises multiple contact islands (126) on the emitter (116) of a bipolar transistor, which act to spread current uniformly across the emitter-base junction. Also included in this invention is segmentation of the emitter diffused region to further improve current uniformity and biasing of the transistor. This invention can be combined with drift region ballasting or back-end ballasting to optimize an ESD protection circuit.

Abstract: A method (50) is provided for processing a graded-density AR silicon surface (14) to provide effective surface passivation. The method (50) includes positioning a substrate or wafer (12) with a silicon surface (14) in a reaction or processing chamber (42). The silicon surface (14) has been processed (52) to be an AR surface with a density gradient or region of black silicon. The method (50) continues with heating (54) the chamber (42) to a high temperature for both doping and surface passivation. The method (50) includes forming (58), with a dopant-containing precursor in contact with the silicon surface (14) of the substrate (12), an emitter junction (16) proximate to the silicon surface (14) by doping the substrate (12). The method (50) further includes, while the chamber is maintained at the high or raised temperature, forming (62) a passivation layer (19) on the graded-density silicon anti-reflection surface (14).

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: This disclosure relates to bipolar transistors, such as heterojunction bipolar transistors, having at least one grading in the collector. One aspect of this disclosure is a bipolar transistor that includes a collector having a high doping concentration at a junction with the base and at least one grading in which doping concentration increases away from the base. In some embodiments, the high doping concentration can be at least about 3×1016 cm?3. According to certain embodiments, the collector includes two gradings. Such bipolar transistors can be implemented, for example, in power amplifiers.

Abstract: Insufficient gain in bipolar transistors (20) is improved by providing an alloyed (e.g., silicided) emitter contact (452) smaller than the overall emitter (42) area. The improved emitter (42) has a first emitter (FE) portion (42-1) of a first dopant concentration CFE, and a second emitter (SE) portion (42-2) of a second dopant concentration CSE. Preferably CSE?CFE. The SE portion (42-2) desirably comprises multiple sub-regions (45i, 45j, 45k) mixed with multiple sub-regions (47m, 47n, 47p) of the FE portion (42-1). A semiconductor-metal alloy or compound (e.g., a silicide) is desirably used for Ohmic contact (452) to the SE portion (42-2) but substantially not to the FE portion (42-1). Including the FE portion (42-1) electrically coupled to the SE portion (42-2) but not substantially contacting the emitter contact (452) on the SE portion (42-2) provides gain increases of as much as ˜278.

Abstract: Bipolar junction transistors are provided in which at least one of an emitter contact, a base contact, or a collector contact thereof is formed by epitaxially growing a doped SixGe1-x layer, wherein x is 0?x?1, at a temperature of less than 500° C. The doped SixGe1-x layer comprises crystalline portions located on exposed surfaces of a crystalline semiconductor substrate and non-crystalline portions that are located on exposed surfaces of a passivation layer which can be formed and patterned on the crystalline semiconductor substrate. The doped SixGe1-x layer of the present disclosure, including the non-crystalline and crystalline portions, contains from 5 atomic percent to 40 atomic percent hydrogen.

Abstract: A bipolar junction transistor (BJT) formed using a fin field-effect transistor (FinFET) complimentary metal-oxide-semiconductor (CMOS) process flow is provided. The BJT includes an emitter fin, a base fin, and a collector fin formed on a substrate. The base fin encloses the emitter fin and collector fin encloses the emitter fin. In some embodiments, the emitter fin, base fin, and collector fin have a square shape when viewed from above and are concentric with each other.

Abstract: Insufficient gain in bipolar transistors (20) is improved by providing an alloyed (e.g., silicided) emitter contact (452) smaller than the overall emitter (42) area. The improved emitter (42) has a first emitter (FE) portion (42-1) of a first dopant concentration CFE, and a second emitter (SE) portion (42-2) of a second dopant concentration CSE. Preferably CSE?CFE. The SE portion (42-2) desirably comprises multiple sub-regions (45i, 45j, 45k) mixed with multiple sub-regions (47m, 47n, 47p) of the FE portion (42-1). A semiconductor-metal alloy or compound (e.g., a silicide) is desirably used for Ohmic contact (452) to the SE portion (42-2) but substantially not to the FE portion (42-1). Including the FE portion (42-1) electrically coupled to the SE portion (42-2) but not substantially contacting the emitter contact (452) on the SE portion (42-2) provides gain increases of as much as ˜278.

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: Methods for fabricating bipolar junction transistors, bipolar junction transistors, and design structures for a bipolar junction transistor. The bipolar junction transistor may include a plurality of emitters that are arranged in distinct emitter fingers. A silicide layer is formed that covers an extrinsic base layer of the bipolar junction transistor and that fills the gaps between adjacent emitters. Non-conductive spacers on the emitter sidewalls electrically insulate the emitters from the silicide layer. The emitters extend through the extrinsic base layer and the silicide layer to contact the intrinsic base layer. The emitters may be formed using sacrificial emitter pedestals in a replacement-type process.

Abstract: A power semiconductor diode is provided. The power semiconductor diode includes a semiconductor substrate having a first emitter region of a first conductivity type, a second emitter region of a second conductivity type, and a drift region of the first conductivity type arranged between the first emitter region and the second emitter region. The drift region forms a pn-junction with the second emitter region. A first emitter metallization is in contact with the first emitter region. The first emitter region includes a first doping region of the first conductivity type and a second doping region of the first conductivity type. The first doping region forms an ohmic contact with the first emitter metallization, and the second doping region forms a non-ohmic contact with the first emitter metallization. A second emitter metallization is in contact with the second emitter region.

Abstract: An LDMOS device includes a substrate having a surface and a gate electrode overlying the surface and defining a channel region in the substrate below the gate electrode. A drain region is spaced apart from the channel region by an isolation region. The isolation region includes a region of high tensile stress and is configured to induce localized stress in the substrate in close proximity to the drain region. The region of high tensile stress in the isolation region can be formed by high-stress silicon oxide or high-stress silicon nitride. In a preferred embodiment, the isolation region is a shallow trench isolation region formed in the substrate intermediate to the gate electrode and the drain region.

Abstract: A semiconductor device comprises: a semiconductor substrate; a plurality of IGBT cells on the semiconductor substrate, each of the IGBT cells including a gate electrode and a first emitter electrode; a first gate wiring on the substrate and being connected to the gate electrode; an interlayer insulating film covering the first emitter electrode and the first gate wiring; and a second emitter electrode on the interlayer insulating film and being connected to the first emitter electrode through an opening of the interlayer insulating film, wherein the second emitter electrode extends above the first gate wiring via the interlayer insulating film.

Abstract: A bipolar transistor, comprising a collector, a base and an emitter, in which the collector comprises a relatively heavily doped region, and a relatively lightly doped region adjacent the base, and in which the relatively heavily doped region is substantially omitted from an intrinsic region of the transistor.

Abstract: Insufficient gain in bipolar transistors (20) is improved by providing an alloyed (e.g., silicided) emitter contact (452) smaller than the overall emitter (42) area. The improved emitter (42) has a first emitter (FE) portion (42-1) of a first dopant concentration CFE, and a second emitter (SE) portion (42-2) of a second dopant concentration CSE. Preferably CSE?CFE. The SE portion (42-2) desirably comprises multiple sub-regions (45i, 45j, 45k) mixed with multiple sub-regions (47m, 47n, 47p) of the FE portion (42-1). A semiconductor-metal alloy or compound (e.g., a silicide) is desirably used for Ohmic contact (452) to the SE portion (42-2) but substantially not to the FE portion (42-1). Including the FE portion (42-1) electrically coupled to the SE portion (42-2) but not substantially contacting the emitter contact (452) on the SE portion (42-2) provides gain increases of as much as ˜278.

Abstract: A method of manufacturing field-emitter arrays by a molding technique includes uniformly controlling a shape of mold holes to obtain field emitter tips having diameters below 100 nm and blunted side edges. Repeated oxidation and etching of a mold substrate formed of single-crystal semiconductor mold wafers is carried out, wherein the mold holes for individual emitters are fabricated by utilizing the crystal orientation dependence of the etching rate.

Abstract: A wafer comprising at least one high Ft HBT and at least one high BVceo HBT having various collector profiles on a common III-V compound semiconductor based wafer. The N+ implant in the collector varies the collector profiles of individual HBTs on the wafer. The method for preparing the device comprises forming of HBT layers up to and including collector layer on non-silicon based substrate, performing ion implantation, annealing for implant activation, and forming remaining HBT layers.

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 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: A process, machine, manufacture, composition of matter, and improvement thereof, and method of making and method of using the same, as well as necessary intermediates, generally relating to the field of semiconductor devices, the structure of transistors, and the structure of compound semiconductor heterojunction bipolar transistors.

Abstract: A method is disclosed for on-the-fly processing at least one structure of a group of structures with a pulsed laser output. The method includes the steps of relatively positioning the group of structures and the pulsed laser output axis with non-constant velocity, and applying the pulsed laser output to the at least one structure of the group of structures during the step of relatively positioning the group of structures and the pulsed laser output axis with non-constant velocity.

Abstract: A light sensor having a light conversion element between first and second electrodes is disclosed. The light conversion element includes a body of semiconductor material having first and second surfaces. The body of semiconductor material is of a first conductivity type and has doping elements in a concentration gradient that creates a first electrostatic field having a magnitude that varies monotonically from the first surface to the second surface. A bias circuit applies a variable potential between the first and second electrodes to create a second electrostatic field having a direction opposite to that of the first electrostatic field and a magnitude determined by the potential. One of the electrodes is transparent to light in a predetermined band of wavelengths. The body of semiconductor material can include an epitaxial body having a monotonically increasing concentration of a doping element as a function of the distance from one the surfaces.

Abstract: A bipolar transistor, comprising a collector, a base and an emitter, in which the collector comprises a relatively heavily doped region, and a relatively lightly doped region adjacent the base, and in which the relatively heavily doped region is substantially omitted from an intrinsic region of the transistor.

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: An ESD protection circuit using a novel substrate-triggered lateral bipolar junction transistor (STLBJT) for providing a discharging path between power rails. The ESD protection circuit comprises an ESD detection circuit and a STLBJT device. The STLBJT device formed in a P-type substrate includes N-type collector and emitter regions coupled to the power rails, respectively. The substrate region between the collector and emitter regions, on which there is no field oxide device, serves as a base of the STLBJT device. The STLBJT device further includes a first P-type region coupled to the ESD detection circuit and a second P-type region coupled to one of the power rails, which are spatially separated from the collector/emitter regions, respectively. The STLBJT device is turned on by substrate-triggering responsive to the signal coming from the ESD detection circuit and establishes the discharging path between the power rails.

Abstract: A bipolar junction transistor may act as a select device for a semiconductor memory. The bipolar junction transistor may be formed of a stack of base and collector layers. Sets of parallel trenches are formed in a first direction down to the base and in a second direction down to the collector. The trenches may be used to form local enhancement implants into the exposed portion of the base and collector in each trench. As a result of the local enhancement implants, in some embodiments, leakage current may be reduced, active current capability may be higher, gain may be higher, base resistance may be reduced, breakdown voltage may be increased, and parasitic effects with adjacent junctions may be reduced.

Abstract: Methods for forming a bipolar junction transistor device are described herein. A method for forming the bipolar junction transistor device may include doping a first portion of a substrate with a first dopant to form a base pick-up region, and after doping the first portion of the substrate, doping a second portion of the substrate with a second dopant to form at least one emitter region. A bipolar junction transistor device may include a floating collector, in which case the bipolar junction transistor device may be operated as a diode for improved emitter current.

Abstract: This invention disclosed a novel method of fully depleted emitter so that the built-in potential between emitter and the base becomes lower and the charge storage between the emitter and base becomes small. This concept also applies to the diodes or rectifiers. With depleted junction, this result in very fast switching of the diodes and transistors. Another novel structure utilizes the strip base structure to achieve lower on resistance of the bipolar transistor. The emitter region of the strip base can be a normal emitter or depleted emitter.

Abstract: A bipolar transistor has a base with an epitaxial base layer and a raised base connection region which in a lateral direction in parallel relationship with the substrate surface encloses the emitter which is surrounded by a spacer of insulating material. The epitaxial base layer is raised in a heightwise direction perpendicularly to the substrate surface. An emitter of a T-shaped cross-sectional profile is separated laterally from the outer base portion by a spacer of insulating material. Its vertical bar of the T-shape adjoins with its lower end the inner base portion.

Abstract: A bipolar junction transistor may act as a select device for a semiconductor memory. The bipolar junction transistor may be formed of a stack of base and collector layers. Sets of parallel trenches are formed in a first direction down to the base and in a second direction down to the collector. The trenches may be used to form local enhancement implants into the exposed portion of the base and collector in each trench. As a result of the local enhancement implants, in some embodiments, leakage current may be reduced, active current capability may be higher, gain may be higher, base resistance may be reduced, breakdown voltage may be increased, and parasitic effects with adjacent junctions may be reduced.

Abstract: A vertical BJT which has a maximal current gain for a photodiode area. According to embodiments, since the BJT can be formed together with the photodiode, and collector current flows up and down based on the double base structure, the magnitude of the current may be increased.

Abstract: A method for the integration of two bipolar transistors in a semiconductor body, wherein, for the first bipolar transistor, a first emitter semiconductor region, a first base semiconductor region, and a first collector semiconductor region are produced. A recombination layer is applied to the first bipolar transistor, which is adjacent to the first emitter semiconductor region or the first collector semiconductor region and is constructed in such a way that charge carriers recombine on the recombination layer, and next, the second bipolar transistor is placed on the recombination layer, wherein a second emitter semiconductor region, a second base semiconductor region, and a second collector semiconductor region are produced on the recombination layer, so that the second emitter semiconductor region or the second collector semiconductor region is adjacent to the recombination layer.

Abstract: A semiconductor emitter structure for emitting charge carriers of a first conductivity type in a base volume of a second conductivity type material neighbored to the emitter structure in a vertical direction, includes multiple emitter volumes of first conductivity tape material having a predetermined lateral dimension in a lateral direction perpendicular to the vertical direction. The emitter volumes are, in the lateral direction, neighbored by semiconductor volumes of second conductivity type material, wherein the predetermined lateral dimension is such that space charges created by second conductivity type carriers laterally diffusing into the emitter volumes from the semiconductor volumes limit a maximum density of first conductivity type carriers within the emitter volumes by more than 20% as compared to emitter volumes of the same lateral dimension not neighbored by semiconductor volumes of the second conductivity type material.

Abstract: A heterojunction bipolar transistor is formed in a semiconductor substrate of a first conductivity type including a collector region. A base region is formed on the substrate and an emitter region is formed over the base region. At least one of the collector, base and emitter regions includes a first region doped with an impurity having a first concentration and a second region doped with the impurity having a second concentration. Noise performance and reliability of the heterojunction bipolar transistor is improved without degrading ac performance.

Abstract: A configuration composed of multiple short emitters still share common DTI regions and a single big piece of base poly. This allows for base current to flow in 4 directions (e.g., 2 dimensions) as opposed to only two. This significantly reduces the base resistance of the transistor that is crucial for better NPN transistor RF performance and high frequency noise performance.

Abstract: A method for producing vertical bipolar transistors having different voltage breakdown and high-frequency performance characteristics on a single die comprises forming, for each of the vertical bipolar transistors, a buried collector region, and base and emitter regions above the buried collector region. The lateral extensions and locations of the base and emitter regions and of the buried collector region are, for each of the vertical bipolar transistors, selected to create an overlap between the base and emitter regions, and the buried collector region, as seen from above, wherein at least some of the overlaps are selected to be different.

Abstract: The present invention provides a a method of fabricating bipolar junction transistors (BJTs) on selected areas of a very thin buried oxide (BOX) using a conventional silicon-on-insulator (SOI) starting wafer with a thick BOX. The reduced BOX thickness underneath the bipolar devices allows for a significantly reduced substrate bias compatible with the CMOS to be applied while maintaining the advantages of a thick BOX underneath the CMOS.

Abstract: An integrated circuit including a buried layer of determined conductivity type in a plane substantially parallel to the plane of a main circuit surface, in which the median portion of this buried layer is filled with a metal-type material.

Abstract: A bipolar transistor and a method for manufacturing the same. The bipolar transistor can include a collector region formed in a substrate, an epitaxial layer formed over the substrate including the collector region, a base region formed in the epitaxial layer, an emitter region formed in the base region, an oxide layer formed on sidewalls of a trench extending through the emitter region, the base region, the epitaxial layer and in the collector region, and a polysilicon layer formed in the trench.

Abstract: An etched grooved GaN-based permeable-base transistor structure is disclosed, along with a method for fabrication of same.

Abstract: A vertical BJT which has a maximal current gain for a photodiode area. According to embodiments, since the BJT can be formed together with the photodiode, and collector current flows up and down based on the double base structure, the magnitude of the current may be increased.

Abstract: Method of producing complementary SiGe bipolar transistors. In a method of producing complementary SiGe bipolar transistors, interface oxide layers (38, 58) for NPN and PNP emitters (44, 64), are separately formed and emitter polysilicon (40, 60) is separately patterned, allowing these layers to be optimized for the respective conductivity type.

Abstract: An etched grooved GaN-based permeable-base transistor structure is disclosed, along with a method for fabrication of same.