Abstract: A Silicon on Insulator (SOI) Integrated Circuit (IC) chip with devices such as a vertical Silicon Controlled Rectifier (SCR), vertical bipolar transistors, a vertical capacitor, a resistor and/or a vertical pinch resistor and method of making the device(s). The devices are formed in a seed hole through the SOI surface layer and insulator layer to the substrate. A buried diffusion, e.g., N-type, is formed through the seed hole in the substrate. A doped epitaxial layer is formed on the buried diffusion and may include multiple doped layers, e.g., a P-type layer and an N-type layer. Polysilicon, e.g., P-type, may be formed on the doped epitaxial layer. Contacts to the buried diffusion are formed in a contact liner.

Abstract: A method and structures are provided for implementing deep trench enabled high current capable bipolar transistor for current switching and output driver applications. A deep oxygen implant is provided in a selected region of substrate. A first deep trench and second deep trench are formed above the deep oxygen implant. The first deep trench is a generally large rectangular box deep trench of minimum width and the second deep trench is a second small area deep trench centered within the first rectangular box deep trench. Ion implantation at relatively high ion pressure and annealing is utilized to form highly doped N+ regions or P+ regions both inside and outside the outside the first deep trench and around the outside the second deep trench region. These regions provide the collector and emitter respectively, and the existing substrate region provides the base region between the collector and emitter regions.

Abstract: A resistor-equipped transistor includes a package that provides an external collector connection node (114, 134), an external emitter connection node (120, 140) and an external base connection node (106, 126). The package contains a substrate upon which a transistor (102, 122), first and second resistors, and first and second diodes are formed. The transistor has an internal collector (118, 138), an internal emitter (120, 140) and an internal base (116, 136) with the first resistor (104, 124) being electrically connected between the internal base and the external base connection node and the second resistor (108, 128) being electrically connected between the internal base and the internal emitter.

Abstract: Disclosed are example bipolar transistors capable of reducing the area of a collector, reducing the distance between a base and a collector, and/or reducing the number of ion implantation processes. A bipolar transistor may includes a trench formed by etching a portion of a semiconductor substrate. A first collector may be formed on the inner wall of the trench. A second collector may be formed inside the semiconductor substrate in the inner wall of the trench. A first isolation film may be formed on the sidewall of the first collector. An intrinsic base may be connected to the third collector. An extrinsic base may be formed on the intrinsic base and inside the first isolation film. A second isolation film may be formed on the inner wall of the extrinsic base. An emitter may be formed by burying a conductive material inside the second isolation film.

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

Abstract: A method for manufacturing a semiconductor power device on a semiconductor substrate supporting a drift region composed of an epitaxial layer by growing a first epitaxial layer followed by forming a first hard mask layer on top of the epitaxial layer; applying a first implant mask to open a plurality of implant windows and applying a second implant mask for blocking some of the implant windows to implant a plurality of dopant regions of alternating conductivity types adjacent to each other in the first epitaxial layer; repeating the first step and the second step by applying the same first and second implant masks to form a plurality of epitaxial layers then carrying out a device manufacturing process on a top side of the epitaxial layer with a diffusion process to merge the dopant regions of the alternating conductivity types as doped columns in the epitaxial layers.

Abstract: An electronic structure comprising: (a) a first metal layer; (b) a second metal layer; (c) and at least one insulator layer located between the first metal layer and the second metal layer, wherein at least one of the metal layers comprises an amorphous multi-component metallic film. In certain embodiments, the construct is a metal-insulator-metal (MIM) diode.

Abstract: Methods are provided for forming a device that includes merged vertical and lateral transistors with collector regions of a first conductivity type between upper and lower base regions of opposite conductivity type that are Ohmically coupled via intermediate regions of the same conductivity type and to the base contact. The emitter is provided in the upper base region and the collector contact is provided in outlying sinker regions extending to the thin collector regions and an underlying buried layer. As the collector voltage increases part of the thin collector regions become depleted of carriers from the top by the upper and from the bottom by the lower base regions. This clamps the collector regions' voltage well below the breakdown voltage of the PN junction formed between the buried layer and the lower base region. The gain and Early Voltage are increased and decoupled and a higher breakdown voltage is obtained.

Abstract: Some aspects of this disclosure relate to a memory device. The memory device includes a collector region having a first conductivity type and which is coupled to a source line of the memory device. A base region is formed over the collector region and has a second conductivity type. A gate structure is coupled to the base region and acts as a shared word line for first and second neighboring memory cells of the memory device. First and second emitter regions are formed over the base region and have the first conductivity type. The first and second emitter regions are arranged on opposite sides of the gate structure. First and second contacts extend upwardly from the first and second emitter regions, respectively, and couple the first and second emitter regions to first and second data storage elements, respectively, of the first and second neighboring memory cells, respectively.

Abstract: An integrated circuit containing a stacked bipolar transistor which includes two bipolar transistors connected in series is disclosed. Each bipolar transistor includes a breakdown inducing feature. The breakdown inducing features have reflection symmetry with respect to each other. A process for forming an integrated circuit containing a stacked bipolar transistor which includes two bipolar transistors connected in series, with breakdown inducing features having reflection symmetry, is also disclosed.

Abstract: One embodiment of an electrostatic protection diode in an integrated circuit includes a base area having at least two bends therein.

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: A band gap reference circuit includes an error-amplifier-based current mirror coupled between a first supply node and a pair of intermediate voltage nodes, and a matched diode pair for providing a proportional-to-absolute temperature (PTAT) current. The matched diode pair includes a first diode connected between a first intermediate voltage node from the pair of intermediate voltage nodes and a second supply node, and a second diode connected in series with a resistor between a second intermediate voltage node from the pair of intermediate voltage nodes and the second supply node. Each diode has a P-N diode junction that is a homojunction.

Abstract: An embodiment of a semiconductor device includes a III-nitride base structure of a first conductivity type, and a III-nitride emitter structure of a second conductivity type having a first surface and a second surface. The second surface is substantially opposite the first surface. The first surface of the III-nitride emitter structure is coupled to a surface of the III-nitride base structure. The semiconductor also includes a first dielectric layer coupled to the second surface of the III-nitride emitter structure, and a spacer coupled to a sidewall of the III-nitride emitter structure and the surface of the III-nitride base structure. The semiconductor also includes a base contact structure with a III-nitride material coupled to the spacer, the surface of the III-nitride base structure, and the first dielectric layer, such that the first dielectric layer and the spacer are disposed between the base contact structure and the III-nitride emitter structure.

Abstract: A bipolar junction transistor built with a mesh structure of cells provided on a semiconductor body is disclosed. The mesh structure has at least one emitter cell with a first type of implant. At least one emitter cell has at least one side coupled to at least one cell with a first type of implant to serve as collector of the bipolar. The spaces between the emitter and collector cells are the intrinsic base of a bipolar device. At least one emitter cell has at least one vortex coupled to at least one cell with a second type of implant to serve as the extrinsic base of the bipolar. The emitter, collector, or base cells can be arbitrary polygons as long as the overall geometry construction can be very compact and expandable. The implant regions between cells can be separated with a space. A silicide block layer can cover the space and overlap into at least a portion of both implant regions.

Abstract: A semiconductor device, including a silicon substrate having a first major surface and a second major surface, a front surface device structure formed in a region of the first major surface, and a rear electrode formed in a region of the second major surface. The rear electrode includes, as a first layer thereof, an aluminum silicon film that is formed by evaporating or sputtering aluminum-silicon onto the second major surface, the aluminum silicon film having a silicon concentration of at least 2 percent by weight and a thickness of less than 0.3 ?m.

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

Abstract: A semiconductor device according to the present invention includes a substrate; a nitride semiconductor layer formed above the substrate and having a laminated structure including at least three layers; a heterojunction bipolar transistor formed in a region of the nitride semiconductor layer; and a field-effect transistor formed in a region of the nitride semiconductor layer, the region being different from the region in which the heterojunction bipolar transistor is formed.

Abstract: High frequency performance of (e.g., silicon) bipolar devices is improved by reducing the extrinsic base resistance Rbx. An emitter, intrinsic base and collector are formed in a semiconductor body. An emitter contact has a region that overlaps a portion of an extrinsic base contact. A sidewall is formed in the extrinsic base contact proximate a lateral edge of the overlap region of the emitter contact. The sidewall is amorphized during or after formation so that when the emitter contact and the extrinsic base contact are, e.g., silicided, some of the metal atoms forming the silicide penetrate into the sidewall so that part of the highly conductive silicided extrinsic base contact extends under the edge of the overlap region of the emitter contact closer to the intrinsic base, thereby reducing Rbx. Smaller Rbx provides transistors with higher fMAX.

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: The product of the breakdown voltage (BVCEO) and the cutoff frequency (fT) of a SiGe heterojunction bipolar transistor (HBT) is increased beyond the Johnson limit by utilizing a doped region with a hollow core that extends down from the base to the heavily-doped buried collector region. The doped region and the buried collector region have opposite dopant types.

Abstract: A higher breakdown voltage transistor has separated emitter, base contact, and collector contact. Underlying the emitter and the base contact are, respectively, first and second base portions of a first conductivity type. Underlying and coupled to the collector contact is a collector region of a second, opposite, conductivity type, having a central portion extending laterally toward, underneath, or beyond the base contact and separated therefrom by the second base portion. A floating collector region of the same conductivity type as the collector region underlies and is separated from the emitter by the first base portion. The collector and floating collector regions are separated by a part of the semiconductor (SC) region in which the base is formed. A further part of the SC region in which the base is formed, laterally bounds or encloses the collector region.

Abstract: Systems and methods are disclosed for processing radio frequency (RF) signals using one or more bipolar transistors disposed on or above a high-resistivity region of a substrate. The substrate may include, for example, bulk silicon, at least a portion of which has high-resistivity characteristics. For example, the bulk substrate may have a resistivity greater than 500 Ohm*cm, such as around 1 kOhm*cm. In certain embodiments, one or more of the bipolar devices are surrounded by a low-resistivity implant configured to reduce effects of harmonic and other interference.

Abstract: Diodes and bipolar junction transistors (BJTs) are formed in IC devices that include fin field-effect transistors (FinFETs) by utilizing various process steps in the FinFET formation process. The diode or BJT includes an isolated fin area and fin array area having n-wells having different depths and a p-well in a portion of the fin array area that surrounds the n-well in the isolated fin area. The n-wells and p-well for the diodes and BJTs are implanted together with the FinFET n-wells and p-wells.

Abstract: A semiconductor element, a manufacturing method thereof and an operating method thereof are provided. The semiconductor element includes a substrate, a first well, a second well, a third well, a fourth well, a bottom layer, a first heavily doping region, a second heavily doping region, a third heavily doping region and a field plane. The first well, the bottom layer and the second well surround the third well for floating the third well and the substrate. The first, the second and the third heavily doping regions are disposed in the first, the second and the third wells respectively. The field plate is disposed above a junction between the first well and the fourth well.

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

Abstract: An integrated circuit containing a stacked bipolar transistor which includes two bipolar transistors connected in series is disclosed. Each bipolar transistor includes a breakdown inducing feature. The breakdown inducing features have reflection symmetry with respect to each other. A process for forming an integrated circuit containing a stacked bipolar transistor which includes two bipolar transistors connected in series, with breakdown inducing features having reflection symmetry, is also disclosed.

Abstract: A method for manufacturing a heterojunction field effect transistor 1 comprises the steps of: epitaxially growing a drift layer 20a on a support substrate 10; epitaxially growing a current blocking layer 20b which is a p-type semiconductor layer on the drift layer 20a at a temperature equal to or higher than 1000° C. by using hydrogen gas as a carrier gas; and epitaxially growing a contact layer 20c on the current blocking layer 20b by using at least one gas selected from the group consisting of nitrogen gas, argon gas, helium gas, and neon gas as a carrier gas.

Abstract: Device structures, fabrication methods, operating methods, and design structures for a silicon controlled rectifier. The method includes applying a mechanical stress to a region of a silicon controlled rectifier (SCR) at a level sufficient to modulate a trigger current of the SCR. The device and design structures include a SCR with an anode, a cathode, a first region, and a second region of opposite conductivity type to the first region. The first and second regions of the SCR are disposed in a current-carrying path between the anode and cathode of the SCR. A layer is positioned on a top surface of a semiconductor substrate relative to the first region and configured to cause a mechanical stress in the first region of the SCR at a level sufficient to modulate a trigger current of the SCR.

Abstract: Provided herein are etching, cleaning and drying methods using a supercritical fluid, and a chamber system for conducting the same. The etching method includes etching the material layer using a supercritical carbon dioxide in which an etching chemical is dissolved, and removing an etching by-product created from a reaction between the material layer and the etching chemical using a supercritical carbon dioxide in which a cleaning chemical is dissolved. Methods of manufacturing a semiconductor device are also provided.

Abstract: A bipolar junction transistor and a manufacturing method for the same are provided. The bipolar junction transistor includes a well region, an emitter electrode, a base electrode, a collector electrode, and a conductive layer. The emitter electrode, the base electrode and the collector electrode are separated from each other by the well region. The conductive layer is on the well region between the base electrode and the collector electrode.

Abstract: A semiconductor structure includes a substrate, a first well having a first conductive type, a second well having a second conductive type, a body region, a first doped region, a second doped region, a third doped region and a field plate. The first and second wells are formed in the substrate. The body region is formed in the second well. The first and second doped regions are formed in the first well and the body region, respectively. The second and first doped regions have the same polarities, and the dopant concentration of the second doped region is higher than that of the first doped region. The third doped region is formed in the second well and located between the first and second doped regions. The third and first doped regions have reverse polarities. The field plate is formed on the surface region between the first and second doped regions.

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: The product of the breakdown voltage (BVCEO) and the cutoff frequency (fT) of a SiGe heterojunction bipolar transistor (HBT) is increased beyond the Johnson limit by utilizing a doped region with a hollow core that extends down from the base to the heavily-doped buried collector region. The doped region and the buried collector region have opposite dopant types.

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

Abstract: 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: A first first-conductivity-type diffusion layer, a first second-conductivity-type diffusion layer, a second first-conductivity-type diffusion layer, and a second second-conductivity-type diffusion layer are arranged in this order. In a region where the second second-conductivity-type diffusion layer and the first-conductivity-type layer are in contact with each other, impurity concentrations thereof are higher in a part in contact with a side face of the second second-conductivity-type diffusion layer than in a part at a bottom surface of the second second-conductivity-type diffusion layer.

Abstract: A semiconductor device includes an n-type first guard ring layer provided between an emitter layer and a collector layer on a surface side of a base layer, and having a higher n-type impurity concentration than the base layer, and an n-type second guard ring layer provided between the first guard ring layer and a buried layer, connected to the first guard ring layer and the buried layer, and having a higher n-type impurity concentration than the base layer. The first guard ring layer has an n-type impurity concentration profile decreasing toward the second guard ring layer side, and the second guard ring layer has an impurity concentration profile decreasing toward the first guard ring layer side.

Abstract: A method of manufacturing a semiconductor apparatus includes forming back surface electrode 4 on back surface of semiconductor wafer 20, that bends convexly toward the front surface side due to back surface electrode 4 being formed; treating the back surface with a plasma for removing the deposits on the back surface; sticking removable adhesive tape 23 to the back surface along the warp thereof for maintaining the bending state of semiconductor wafer 20 after the step of sticking; electrolessly plating to form film 26 on the front surface of semiconductor wafer 20; peeling off removable adhesive tape 23; cutting out semiconductor chips; and mounting the semiconductor chip by bonding with a solder for manufacturing a semiconductor apparatus. The manufacturing method prevents external appearance anomalies from occurring on the back surface electrode, improves the reliability, and allows manufacture of the semiconductor apparatuses with a high throughput of non-defective products.

Abstract: An asymmetric silicon-on-insulator (SOI) junction field effect transistor (JFET) and a method. The JFET includes a bottom gate on an insulator layer, a channel region on the bottom gate and, on the channel region, source/drain regions and a top gate between the source/drain regions. STIs isolate the source/drain regions from the top gate and a DTI laterally surrounds the JFET to isolate it from other devices. Non-annular well(s) are positioned adjacent to the channel region and bottom gate (e.g., a well having the same conductivity type as the top and bottom gates can be connected to the top gate and can extend down to the insulator layer, forming a gate contact on only a portion of the channel region, and/or another well having the same conductivity type as the channel and source/drain regions can extend from the source region to the insulator layer, forming a source-to-channel strap).

Abstract: A semiconductor device fabricating method is described. The semiconductor device fabricating method comprises forming an epitaxial layer on a substrate, wherein the epitaxial layer is the same conductive type as the substrate. A first doped region having the different conductive type from the epitaxial layer is formed in the epitaxial layer. An annealing process is performed to diffuse dopants in the first doped region. A second doped region and an adjacent third doped region are formed in the first doped region. The second doped region is a different conductive type from that of the first doped region, and the third doped region is the same conductive type as that of the first doped region. A gate structure is formed on the epitaxial layer covering a portion of the second and the third doped regions.

Abstract: The self heating of a high-performance bipolar transistor that is formed on a fully-isolated single-crystal silicon region of a silicon-on-insulator (SOI) structure is substantially reduced by forming a Schottky structure in the same fully-isolated single-crystal silicon region as the bipolar transistor is formed.

Abstract: In a bipolar semiconductor device such that electrons and holes are recombined in a silicon carbide epitaxial film grown from the surface of a silicon carbide single crystal substrate at the time of on-state forward bias operation; an on-state forward voltage increased in a silicon carbide bipolar semiconductor device is recovered by shrinking the stacking fault area enlarged by on-state forward bias operation. In a method of this invention, the bipolar semiconductor device in which the stacking fault area enlarged and the on-state forward voltage has been increased by on-state forward bias operation, is heated at a temperature of higher than 350° C.

Abstract: A problem in the conventional technique is that metal contamination on a silicon carbide surface is not sufficiently removed in a manufacturing method of a semiconductor device using a monocrystalline silicon carbide substrate. Accordingly, there is a high possibility that the initial characteristics of a manufactured silicon carbide semiconductor device are deteriorated and the yield rate is decreased. Further, it is conceivable that the metal contamination has an adverse affect even on the long-term reliability of a semiconductor device. In a manufacturing method of a semiconductor device using a monocrystalline silicon carbide substrate, there is applied a metal contamination removal process, on a silicon carbide surface, including a step of oxidizing the silicon carbide surface and a step of removing a film primarily including silicon dioxide formed on the silicon carbide surface by the step.

Abstract: Methods, devices, and systems for using and forming vertically base-connected bipolar transistors have been shown. The vertically base-connected bipolar transistors in the embodiments of the present disclosure are formed with a CMOS fabrication technique that decreases the transistor size while maintaining the high performance characteristics of a bipolar transistor.

Abstract: In accordance with the invention, there are various methods of making an integrated circuit comprising a bipolar transistor. According to an embodiment of the invention, the bipolar transistor can comprise a substrate, a collector comprising a plurality of alternating doped regions, wherein the plurality of alternating doped regions alternate in a lateral direction from a net first conductivity to a net second conductivity, and a collector contact in electrical contact with the collector. The bipolar transistor can also comprise a heavily doped buried layer below the collector, a base in electrical contact with a base contact, wherein the base is doped to a net second conductivity type and wherein the base spans a portion of the plurality of alternating doped regions, and an emitter disposed within the base, the emitter doped to a net first conductivity, wherein a portion of the alternating doped region under the emitter is doped to a concentration of less than about 3×1012 cm?2.

Abstract: A method of forming a MOSFET is provided. The method comprises forming a relatively thin layer of dielectric on a substrate. Depositing a gate material layer on the relatively thin layer of dielectric. Removing portions of the gate material layer to form a first and second gate material regions of predetermined lateral lengths. Introducing a first conductivity type dopant in the substrate to form a top gate using first edges of the first and second gate material regions as masks, Introducing a second conductivity dopant of high dopant density in the substrate to form a drain region adjacent the surface of the substrate using a second edge of the second gate material region as a mask to form a first edge of the drain region, wherein a spaced distance between the top gate and the drain region is determined by the lateral length of the second gate material region.

Abstract: A method of forming a MOSFET is provided. The method comprises forming a relatively thin layer of dielectric on a substrate. Depositing a gate material layer on the relatively thin layer of dielectric. Removing portions of the gate material layer to form a first and second gate material regions of predetermined lateral lengths. Introducing a first conductivity type dopant in the substrate to form a top gate using first edges of the first and second gate material regions as masks, Introducing a second conductivity dopant of high dopant density in the substrate to form a drain region adjacent the surface of the substrate using a second edge of the second gate material region as a mask to form a first edge of the drain region, wherein a spaced distance between the top gate and the drain region is determined by the lateral length of the second gate material region.