Abstract: An insulated gate semiconductor device comprising an insulator substrate having provided thereon a source and a drain region; a channel region being incorporated between said source and said drain regions, said channel region comprising a polycrystalline, a single crystal, or a semi-amorphous semiconductor material; and a region provided under said channel region, said region comprising an amorphous material containing the same material as that of the channel region as the principal component, or said region comprising a material having a band gap larger than said channel region. A process for fabricating the device is also disclosed.

Abstract: The present invention provides a semiconductor device having an active region bent at right angles, wherein an interval between patterns for the active region and a gate is set larger than an arc radius of a curved portion (portion where a line is brought to arcuate form) formed inside the pattern for the bent active region. By defining and designing the pattern interval, the curved portion of the active region do not overlap the gate pattern, and the difference between a device characteristic and a designed value can be prevented from increasing.

Abstract: A semiconductor device includes a fully silicided first gate interconnect formed on a semiconductor substrate, a first sidewall formed on a side of the first gate interconnect, and impurity diffusion layers formed in an active region of the semiconductor substrate. A shared contact plug is formed in an interlayer dielectric formed on the semiconductor substrate so as to be connected to the first gate interconnect and associated one of the impurity diffusion layers. The first gate interconnect is formed, at its part connected to the shared contact plug, with a projection part projecting beyond the first sidewall.

Abstract: An electrostatic discharge protection circuit comprises a pad, a first transistor, a second transistor, and a diode. Wherein, the first transistor comprises the gate, a first source-drain, and a second source-drain. The first source-drain of the first transistor is electrically coupled to the pad, and the second source-drain of the first transistor is electrically coupled to a first power line. The first source-drain of the second transistor is electrically coupled to the gate of the first transistor, the second source-drain of the second transistor is electrically coupled to the first power line, and the gate of the second transistor is electrically coupled to a second power line. The diode includes a first terminal coupled to the gate of the first transistor, and a second terminal coupled to the pad. In addition, the diode and the first transistor together form a silicon controlled rectifier (SCR).

Abstract: An exemplary ESD protection circuit includes first and second sets of transistors and an ESD discharge transistor. Each of the transistors includes a source electrode, a drain electrode, and a gate electrode. The drain electrodes and gate electrodes of each of the transistors are connected to each other, and the source electrodes of the transistors are respectively connected to the drain electrodes of the next adjacent transistors in both sets of the transistors. The gate electrode of the ESD transistor, the source electrodes of last transistors of the first and second sets of the transistors are connected to each other, the source electrode of the ESD transistor is connected to the drain electrode of a first transistor of the first set of the transistors, and the drain electrode of the ESD transistor is connected to the drain electrode of a first transistor of the second set of the transistors.

Abstract: A chip is provided which includes an active semiconductor region and a field effect transistor (“FET”) having a channel region, a source region and a drain region all disposed within the active semiconductor region. The FET has a longitudinal direction in a direction of a length of the channel region, and a transverse direction in a direction of a width of the channel region. A dielectric stressor element having a horizontally extending upper surface extends below a portion of the active semiconductor region. The dielectric stressor element shares an edge with the active semiconductor region, the edge extending in a direction away from the upper surface. In particular structures, two or more dielectric stressor elements are provided at locations opposite from each other in the longitudinal and/or transverse directions of the FET.

Abstract: A process of manufacturing a semiconductor circuit includes providing a substrate layer, forming a metal layer above the substrate layer, incorporating circuit components in the substrate layer, and electrically connecting the circuit components to the metal layer. The process includes configuring the circuit components to perform an electrical function of the semiconductor circuit. The semiconductor circuit has a specific electrical conductivity between the substrate layer and the metal layer based on the electrical function performed. The process includes increasing the electrical conductivity between the substrate layer and the metal layer compared with the specific electrical conductivity.

Abstract: MOS transistors have an active region defined in a portion of a semiconductor substrate, a gate electrode on the active region, and drain and source regions in the substrate. First and second lateral protrusions extend from the lower portions of respective sidewalls of the gate electrode. The drain region has a first lightly-doped drain region under the first lateral protrusion, a second lightly-doped drain region adjacent the first lightly-doped drain region, and a heavily-doped drain region adjacent to the second lightly-doped drain region. The source region similarly has a first lightly-doped source region under the second lateral protrusion, a second lightly-doped source region adjacent the first lightly-doped source region, and a heavily-doped source region adjacent to the second lightly-doped source region. The second lightly-doped regions are deeper than the first lightly-doped regions, and the gate electrode may have an inverted T-shape.

Abstract: A semiconductor integrated circuit device includes a cell well, a memory cell array formed on the cell well and having a memory cell area and cell well contact area, first wiring bodies arranged in the memory cell area, and second wiring bodies arranged in the cell well contact area. The layout pattern of the second wiring bodies is the same as the layout pattern of the first wiring bodies. The cell well contact area comprises cell well contacts that have the same dopant type as the cell well and that function as source/drain regions of dummy transistors formed in the cell well contact area.

Abstract: A lateral bipolar CMOS integrated circuit having an inverter circuit including an n-channel MOS transistor and a p-channel MOS transistor, and having four terminals of: a gate input terminal Vin connected with the gates of the n-channel MOS transistor and the p-channel MOS transistor; an output terminal Vout connected with the drains of the n-channel MOS transistor and the p-channel MOS transistor; a p-type base terminal connected with a p-type substrate of the n-channel MOS transistor; and an n-type base terminal connected with an n-type substrate of the p-channel MOS transistor. The n-channel MOS transistor operates in a hybrid mode which is the hybrid of an operation mode of the MOS transistor and that of an npn lateral bipolar transistor which is inherent in the n-channel MOS transistor. The p-channel MOS transistor operates in a hybrid mode which is the hybrid of an operation mode of the MOS transistor and that of a pnp lateral bipolar transistor which is inherent in the p-channel MOS transistor.

Abstract: A stress nitride structure is formed on an integrated circuit field effect transistor by high density plasma (HDP) depositing a first stress nitride layer on the integrated circuit field effect transistor and then plasma enhanced chemical vapor depositing (PECVD) a second stress nitride layer on the first stress nitride layer. The first stress nitride layer is non-conformial and the second stress nitride layer is conformal. Related structures also are described.

Abstract: By providing a tungsten nitride barrier layer for a contact plug, well-approved copper-based via formation techniques may be used to form a highly conductive contact plug, thereby significantly reducing the series resistance compared to conventional tungsten-based contact plugs. The tungsten nitride barrier layer may be deposited by ALD techniques, which exhibit superior step coverage and thus allow a reliable coverage of exposed surfaces of the contact opening, thereby providing the potential for using copper or copper alloys even in the vicinity of highly sensitive device areas of circuit elements, such as transistors and the like.

Abstract: An EEPROM having a charge storage element, i.e., a floating gate, in the substrate adjacent to vertically separated source and drain electrodes. An electrically transparent poly control gate allows relatively low voltages to be used for program, erase, and read operations when a plurality of similar devices are arranged in a memory array. A second poly member, called a tunnel poly member, communicates with source and drain electrodes in synchronism with the poly control gate to provide charge carriers to the floating gate. Manufacturing involves a series of layers with minimal needs for photolithography.

Abstract: A chip is provided which includes an active semiconductor region and a field effect transistor (“FET”) having a channel region, a source region and a drain region all disposed within the active semiconductor region. The FET has a longitudinal direction in a direction of a length of the channel region, and a transverse direction in a direction of a width of the channel region. A first dielectric stressor element having a horizontally extending upper surface extends below a portion of the active semiconductor region, such as a northwest portion of the active semiconductor region. A second dielectric stressor element having a horizontally extending upper surface extends below a second portion of the active semiconductor region, such as a southeast portion of the active semiconductor region. Each of the first and second dielectric stressor elements shares an edge with the active semiconductor region, the edges extending in directions away from the upper surface.

Abstract: A thin film transistor of the present invention has an active layer including at least source, drain and channel regions formed on an insulating surface. A high resistivity region is formed between the channel region and each of the source and drain regions. A film capable of trapping positive charges therein is provided on at least the high resistivity region so that N-type conductivity is induced in the high resistivity region. Accordingly, the reliability of N-channel type TFT against hot electrons can be improved.

Abstract: A semiconductor device may include first, second, and third semiconductor layers. The first and third layers may have a first dopant type, and the second layer may have a second dopant type. A first region within the third semiconductor layer may have the second dopant type. A second region between the first region and the second semiconductor layer may have the first dopant type. A third region above the second region may have the first dopant type. A fourth semiconductor region adjacent to the third region may have a first concentration of the second dopant type. A source contact region may have a second concentration of the second dopant type adjacent to the third semiconductor region and adjacent to the fourth semiconductor region. The second concentration may be higher than the first concentration.

Abstract: A semiconductor device includes a substrate, a multilayered assembly of high k dielectric materials formed on the substrate, and a first conducting material formed on the upper layer of the assembly of high k dielectric materials. The multilayered high k dielectric assembly includes a lower layer, an upper layer, and a diffusion barrier layer formed between the lower and upper dielectric layers. The diffusion barrier layer has a greater affinity for oxygen than the upper and lower layers. The first conducting layer includes a conducting compound of at least a metal element and oxygen.

Abstract: A wafer level package for a surface acoustic wave device and a fabrication method thereof include a SAW device formed with a SAW element on an upper surface of a device wafer; a cap wafer joined on an upper part of the SAW element; a cavity part housing the SAW element between the cap wafer and the SAW device; a cap pad formed on an upper surface of the cap wafer; and a metal line formed to penetrate through the cap wafer to electrically connect the cap pad and the SAW element, the device wafer and the cap wafer being made of the same materials.

Abstract: The present invention is directed to the use of perovskite manganite thin films and other magnetic films that exhibit both planar Hall effect and biaxial magnetic anisotropy to form the active area in magnetic sensor devices and in magnetic bit cells used in magnetoresistive random access memory (MRAM) devices. The manganite thin films of the invention are ferromagnetic manganites of the formula R1-xAxMnO3, wherein R is a rare-earth metal, A is an alkaline earth metal, and x is generally between about 0.15 and about 0.5.

Abstract: A magnetoresistive element includes a magnetic recording layer which records information as a magnetization direction changes upon supplying a bidirectional current in an out-of-plane direction, a magnetic reference layer which has a fixed magnetization direction, and a nonmagnetic layer which is provided between the magnetic recording layer and the magnetic reference layer. The magnetic recording layer includes an interface magnetic layer which is provided in contact with the nonmagnetic layer and has a first magnetic anisotropy energy, and a magnetic stabilizing layer which has a second magnetic anisotropy energy higher than the first magnetic anisotropy energy.

Abstract: An improved magnetoresistive memory device has a reduced distance between the magnetic memory element and a conductive memory line used for writing to the magnetic memory element. The reduced distance is facilitated by forming the improved magnetoresistive memory device according to a method that includes forming a mask over the magnetoresistive memory element and forming an insulating layer over the mask layer, then removing portions of the insulating layer using a planarization process. A conductive via can then be formed in the mask layer, for example using a damascene process. The conductive memory line can then be formed over the mask layer and conductive via.

Abstract: An apparatus comprising an integrated circuit having a plurality of devices each having device characteristics, and a waveguide structure coupled to the integrated circuit, wherein photons provided to the waveguide structure are directed to one or more devices of the plurality of devices and can alter the device characteristics of the device or devices.

Abstract: A CIS and a method for manufacturing the same are provided. The CIS includes an interlayer insulation layer formed on a substrate having a photodiode and a transistor formed thereon; a plurality of color filters formed on the interlayer insulation layer and spaced a predetermined interval apart from each other; a metal sidewall formed to fill the predetermined interval between the plurality of the color filters; and a microlens formed on each of the plurality of color filters.

Abstract: A CMOS image sensor includes a semiconductor substrate with an active area. A photodiode and a plurality of transistors may be formed on the active area. The active area has a portion with a variable width below a reset transistor.

Abstract: An image pickup device mounting structure includes an image pickup device, a reinforcing plate, and a flexible circuit board having at least one electrical component mounted thereon, wherein the reinforcing plate; the image pickup device and a part of the flexible circuit board are superimposed on each other, the reinforcing plate includes at least one cutout portion; and the electrical component is positioned on the part of the flexible circuit board and within the cutout portion.

Abstract: Microelectronic imagers with shaped image sensors and methods for manufacturing curved image sensors. In one embodiment, a microelectronic imager device comprises an imaging die having a substrate, a curved microelectronic image sensor having a face with a convex and/or concave portion at one side of the substrate, and integrated circuitry in the substrate operatively coupled to the image sensor. The imaging die can further include external contacts electrically coupled to the integrated circuitry and a cover over the curved image sensor.

Abstract: The present invention provides an avalanche photodiode capable of raising productivity. An n-type InP buffer layer, an n-type GaInAs light absorption layer, an n-type GaInAsP transition layer, an n-type InP electric field adjusting layer, an n-type InP avalanche intensifying layer, an n-type AlInAs window layer and a p-type GaInAs contact layer are grown in order on an n-type InP substrate. Next, Be is ion-injected into an annular area along the outer periphery of a light receiving area which is activated by heat treatment so as to form an inclined joint, to obtain a p-type peripheral area for preventing an edge break down. Further, Zn is selectively diffused thermally into the light receiving area until it reaches the n-type InP avalanche intensifying layer so as to form a p-type conductive area.

Abstract: An improved Fast Recovery Diode comprises a main PN junction defining a central conduction region for conducting high current in a forward direction and a peripheral field spreading region surrounding the central conduction region for blocking high voltage in the reverse direction. The main PN junction has an avalanche voltage equal to or lower than an avalanche voltage of the peripheral field spreading region so substantially the entire said main PN junction participates in avalanche conduction. This rugged FRED structure can also be formed in MOSFETS, IGBTS and the like.

Abstract: A solid-state imaging device includes a pixel array area in which an unit pixel including a photoelectric conversion element converting optical signals to signal charges and a transfer gate transferring the signal charges which have been photoelectrically converted in the photoelectric conversion element is two-dimensionally arranged in a matrix form, a supply voltage control means for supplying plural first control voltages sequentially to a control electrode of the transfer gate, and a driving means for performing driving of reading out signal charges transferred by the transfer gate when the plural first control voltages are sequentially applied twice and more.

Abstract: A semiconductor device includes a substrate comprising a material selected from the group consisting of AlN, SiC, GaN, sapphire and combinations thereof. An n+ type epitaxial layer is disposed above substrate and comprises GaN or AlGaN. An n? type epitaxial layer is disposed above substrate and comprises GaN or AlGaN. A p+-n junction grid comprising p+ GaN or p+ AlGaN is formed on selective areas of the n? type epitaxial layer. A metal layer is disposed over the p+-n junction grid and forms a Schottky contact. Another metal layer is deposited on one of the substrate and the n+ type epitaxial layer and forms a cathode electrode. A method of fabricating a semiconductor device is provided and includes forming a p+-n junction grid on a drift layer comprising GaN or AlGaN.

Abstract: A photodiode with a semiconductor intrinsic light absorption layer has at least one p-doped light absorption layer or an n-doped light absorption layer, and preferably both. The diode also has a cathode electrode and an anode electrode electrically coupled with the p-doped light absorption layer or the n-doped light absorption layer.

Abstract: A pixel cell with controlled leakage is formed by modifying the location and gate profile of a high dynamic range (HDR) transistor. The HDR transistor may have the gate profile of a transfer gate or a reset gate. The HDR transistor may be located on a side of the photodiode that is the same, opposite to, or perpendicular to the transfer gate. The leakage through the HDR transistor may be controlled by modifying the photodiode implants around the transistor. The photodiode implants at the HDR transistor may be placed similarly to the implants at the transfer gate. However, when the photodiode implants are moved away from the HDR transistor, leakage is reduced. When the photodiode implants are moved farther under the HDR transistor, leakage is increased to the extent desirable. The leakage through the HDR transistor may also be controlled by applying a voltage across the transistor.

Abstract: A photo thin film transistor having a photoconductive layer including a chalcogenide element and a unit cell of an image sensor using the same are provided. The photo thin film transistor includes a glass substrate; a photoconductive layer that is formed of GST including a chalcogenide element, is disposed on the glass substrate, and absorbs light and generates an optical current; a source electrode and a drain electrode that are formed on respective sides of the photoconductive layer and form a path for the optical current generated by the photoconductive layer; a gate insulating layer formed on the photoconductive layer; and a gate electrode that is formed on the gate insulating layer and turns the optical current on or off. The photo thin film transistor includes amorphous GST including a chalcogenide element forming a photoconductive layer, thereby providing very high photoconductivity.

Abstract: Provided is a manufacturing method of a solid-state imaging device, which is able to realize a solid-state imaging device whose reflection prevention coating is even and that does not have image noise in case of adopting a spincoating method in applying a material of the reflection prevention coating onto microlenses of the solid-state imaging device. In the solid-state imaging device 1 according to the present invention, a barrier wall pattern 7 is formed, as a step alleviating structure, in dicing areas 5X formed between adjacent imaging areas 9. The barrier wall pattern 7 has a rectangular sectional form. With use of the barrier wall pattern 7 in the spincoating method, reflection prevention coating 8 is coated onto the microlenses 6 more evenly than in conventional cases.

Abstract: In a variable field device for process automation technology, wherein the field device is connected to an external communication medium for data transmission and wherein functionalities of the field device are application-specifically adaptable, the field device provides only few, basic functions (e.g. measured value production) and application-specific functionalities (e.g. frequency/pulse outputs) are implemented by separate function units, which are connected to the communication medium.

Abstract: The present invention relates to a manufacturing method for a semiconductor device that includes, at least, the step of forming a drift region of a second conductivity type provided with a low concentration region in the semiconductor substrate on, at least, one side in the channel length direction of the gate electrode by means of impurity ion implantations with predetermined implantation angles with four different directions; and the step of forming a high concentration region of the second conductivity type surrounded by the drift region, with the exception of the low concentration region. A semiconductor device having a drift region that can be miniaturized without increase in the number of manufacturing steps as well as a manufacturing method for the same can be provided according to the above described method.

Abstract: A semiconductor device including: a semiconductor layer; a gate insulating layer formed above the semiconductor layer; a gate electrode formed above the gate insulating layer; a channel region formed in the semiconductor layer; a source region and a drain region formed in the semiconductor layer; and an offset insulating layer formed in the semiconductor layer and at least between the channel region and the source region and between the channel region and the drain region, a ratio of a length in a depth direction and a length in a channel length direction of the offset insulating layer being one or less.

Abstract: Provided is a manufacturing method of a semiconductor integrated circuit device having a plurality of first MISFETs in a first region and a plurality of second MISFETs in a second region, which comprises forming a first insulating film between two adjacent regions of the first MISFET forming regions in the first region and the second MISFET forming regions in the second region; forming a second insulating film over the surface of the semiconductor substrate between the first insulating films in each of the first and second regions; depositing a third insulating film over the second insulating film; forming a first conductive film over the third insulating film in the second region; forming, after removal of the third and second insulating films from the first region, a fourth insulating film over the surface of the semiconductor substrate in the first region; and forming a second conductive film over the fourth insulating film; wherein the third insulating film remains over the first insulating film in the se

Abstract: A memory cell includes a first electrode, a second electrode, and phase-change material between the first electrode and the second electrode. The phase-change material defines a narrow region. The memory cell includes first insulation material having a first thermal conductivity and contacting the phase-change material. A maximum thickness of the first insulation material contacts the narrow region. The memory cell includes a second insulation material having a second thermal conductivity greater than the first thermal conductivity and contacting the first insulation material.

Abstract: A three-dimensionally integrated electronic assembly includes a substrate that includes active circuitry formed therein. At least one electronic component (e.g., an integrated circuit chip, active component, passive component, active assembly, and/or passive assembly) is mounted on the substrate. At least one redistribution connection is disposed between the substrate and at least one electronic component. Each electronic component is electrically coupled to the substrate and/or another electronic component mounted on the substrate by means of the redistribution connection.

Abstract: A semiconductor device including: a semiconductor layer; a transistor formed in the semiconductor layer; a first interlayer dielectric formed above the semiconductor layer; a plurality of first interconnect layers formed above the first interlayer dielectric; a second interlayer dielectric formed over the first interlayer dielectric and the first interconnect layers; a plurality of second interconnect layers and an electrode pad which are formed above the second interlayer dielectric, the second interconnect layers being uppermost interconnects; a passivation layer formed over the second interlayer dielectric, the second interconnect layers, and the electrode pad; and an opening formed in the passivation layer to expose at least part of the electrode pad, a minimum distance between the second interconnect layers being greater than a minimum distance between the first interconnect layers.

Abstract: In an embodiment, a semiconductor device includes a first fuse cutting portion in which fuse lines are arranged transversely adjacent to each other, a first runner portion in which runner lines connected to the fuse lines are arranged transversely adjacent to each other but at smaller intervals than those of the fuse lines, and a first connection portion having connection lines between the fuse lines and the runner lines. An insulating barrier layer covers the connection portions so that post-process residues from fuse cutting do not cause electrical shorts between the closely formed runner lines.

Abstract: A plate to plate capacitor has a first plate, a second plate, and an insulating medium separating the first plate from the second plate. The first plate and the second plate are adapted and arranged to form an interlaced structure in which multiple capacitance surface areas in different planes, such as horizontal and vertical, are provided between said first and second plates. The plate to plate capacitor can be formed as a stack of layers in which one or more alternating first and third insulating layers each have first and second conductive lines configured therein and in which one or more second insulating layers having conductive vias formed therein interpose respective first and third insulating layers. The first and second conductive lines in the first insulating layer(s) are interconnected by the conductive vias to the first and second conductive lines, respectively, in the third layer(s) so as to interlace the first and second metal conductive lines together.

Abstract: A capacitor incorporated into an integrated electronic circuit comprises two plates and a series of intermediate layers placed between the plates. The intermediate layers are alternately insulating layers and conducting layers, and each conducting layer is electrically isolated from the rest of the circuit. Such a capacitor may have a high breakdown voltage.

Abstract: Low inductance capacitors include electrodes that are arranged among dielectric layers and oriented such that the electrodes are substantially perpendicular to a mounting surface. Vertical electrodes are exposed along a device periphery to determine where termination lands are formed, defining a narrow and controlled spacing between the lands that is intended to reduce the current loop area, thus reducing the component inductance. Further reduction in current loop area and thus component equivalent series inductance (ESL) may be provided by interdigitated terminations. Terminations may be formed by various electroless plating techniques, and may be directly soldered to circuit board pads. Terminations may also be located on “ends” of the capacitors to enable electrical testing or to control solder fillet size and shape. Two-terminal devices may be formed as well as devices with multiple terminations on a given bottom (mounting) surface of the device.

Abstract: A high resistance CMOS resistor with a relatively small die size is provided. The CMOS resistor includes a p-field region disposed in a n-well of a substrate and a pair of p-type contact regions respectively disposed beside a field oxide layer in the n-well. The pair of p-type contact regions are respectively connected to two sides of the p-field region as a first ohmic contact and a second ohmic contact for the CMOS resistor. The CMOS resistor according to the present invention has a resistance of, for example, 10 k?-20 k? per square.

Abstract: An integrated circuit for feeding data acquisition circuits is provided. The integrated circuit including an inverter application having a half-bridge driver for driving high and low side switches connected in a half bridge, a data acquisition circuit formed in monolithic high voltage technology, and a Low Voltage Floating Supply (LVFS) circuit for providing voltage to the data acquisition circuit, the LVFS circuit being formed in a floating n-epi pocket biased with a voltage that is lower than a maximum value of a voltage present in the n-epi pocket.

Abstract: A structure comprises a single wafer with a first subcollector formed in a first region having a first thickness and a second subcollector formed in a second region having a second thickness, different from the first thickness. A method is also contemplated which includes providing a substrate including a first layer and forming a first doped region in the first layer. The method further includes forming a second layer on the first layer and forming a second doped region in the second layer. The second doped region is formed at a different depth than the first doped region. The method also includes forming a first reachthrough in the first layer and forming a second reachthrough in second layer to link the first reachthrough to the surface.

Abstract: A bipolar transistor and a method for manufacturing the same are described. A light-doped layer is provided between the base layer and the emitter layer of the bipolar transistor to effectively reduce the invalid current that flows from the base layer back to the emitter layer and increase the required forward bias voltage located between the base layer and the emitter layer to enhance the current gain. The bipolar transistor at least includes a semiconductor substrate, a deep-buried layer formed on the semiconductor substrate, an epitaxy layer formed on the deep-buried layer, a collector layer formed on the epitaxy layer, a base formed on the epitaxy layer, an emitter layer formed within the base layer, and a light-doped layer formed between the base layer and the emitter layer.

Abstract: A method is provided for fabricating a bipolar transistor in which a collector layer is formed which includes an active portion having a relatively high dopant concentration and a second portion which has a lower dopant concentration. An epitaxial intrinsic base layer is formed to overlie the collector layer in conductive communication with the active portion of the collector layer. A low-capacitance region is formed laterally adjacent to the second portion of the collector layer, the low-capacitance region including a dielectric region disposed in an undercut directly underlying the intrinsic base layer. An emitter layer is formed to overlie the intrinsic base layer.