Abstract: Methods for fabricating CMOS image sensor devices are provided, wherein active pixel sensors are constructed with non-planar transistors having vertical gate electrodes and channels, which minimize the effects of image lag and dark current.

Abstract: A triple-well CMOS structure having reduced latch-up susceptibility and a method of fabricating the structure. The method includes forming a buried P-type doped layer having low resistance under the P-wells and N-wells in which CMOS transistors are formed and forming a gap in a buried N-type doped layer formed in the P-wells, the is gap aligned under a contact to the P-well. The buried P-type doped layer and gap in the buried N-type doped layer allow a low resistance hole current path around parasitic bipolar transistors of the CMOS transistors.

Abstract: A method of manufacturing a semiconductor integrated circuit (IC) device that integrates a TLPM (trench lateral power MOSFET) and one or more planar semiconductor devices on a semiconductor substrate. In manufacturing the semiconductor IC device according to one embodiment, a trench etching forms a trench. A p-type body region, an n-type expanded drain region, and a thick oxide film are formed. A second trench etching deepens the trench. Gate oxide films and gate electrodes of the TLPM, an NMOSFET, and a PMOSFET are formed. P-type base regions of the TLPM and an NPN bipolar transistor are formed. An n-type source and drain region of the TLPM, and n-type diffusion regions of the NMOSFET and the NPN bipolar transistor are formed. P-type diffusion regions of the PMOSFET and the NPN bipolar transistor are formed. An interlayer oxide film, a contact electrode, and constituent metal electrodes are formed.

Abstract: Complementary metal-oxide-semiconductor (CMOS) integrated circuits with bipolar transistors and methods for fabrication are provided. A bipolar transistor may have a lightly-doped base region. To reduce the resistance associated with making electrical contact to the lightly-doped base region, a low-resistance current path into the base region may be provided. The low-resistance current path may be provided by a base conductor formed from heavily-doped epitaxial crystalline semiconductor. Metal-oxide-semiconductor (MOS) transistors with narrow gates may be formed on the same substrate as bipolar transistors. The MOS gates may be formed using a self-aligned process in which a patterned gate conductor layer serves as both an implantation mask and as a gate conductor. A base masking layer that is separate from the patterned gate conductor layer may be used as an implantation mask for defining the lightly-doped base region.

Abstract: A method in the fabrication of an integrated bipolar circuit comprises the steps of: providing a p-type substrate; forming in the substrate a buried n+-type region and an n-type region above the buried n+-type region; forming field isolation areas around the n-type region; forming a PMOS gate region on the n-type region; forming a diffused n+-type contact from the upper surface of the substrate to the buried n+-type region; the contact being separated from the n-type region; forming a p-type polysilicon source on the n-type region; forming a p-type source in the n-type region; forming a p-type drain in the n-type region; and connecting the PMOS transistor structure to operate as a PNP transistor, wherein the source is connected to the gate and constitutes an emitter of the PNP transistor; the drain constitutes a collector of the PNP transistor; and the n-type region constitutes a base of the PNP transistor.

Abstract: Provided is a technique of improving the properties of a bipolar transistor. Described specifically, upon formation of a collector electrode around a base mesa by the lift-off method, a resist film is formed over connection portions between the outer periphery of a region OA1 and a region in which the base mesa 4a is formed, followed by successive formation of gold germanium (AuGe), nickel (Ni) and Au in the order of mention over the entire surface of a substrate so that the stacked film of them will not become an isolated pattern. As a result, the stacked film over the base mesa 4a is connected to a stacked film at the outer periphery of the region OA1, facilitating peeling of the stacked film over the base mesa 4a. In addition, generation of side etching upon formation of a via hole extending from the back side of the substrate to a backside via electrode is reduced by forming the backside via electrode using a material such as WSi which hardly reacts with an n type GaAs layer or n type InGaAs layer.

Abstract: A method of fabricating an LDMOS transistor and a conventional CMOS transistor together on a substrate. A P-body is implanted into a source region of the LDMOS transistor. A gate oxide for the conventional CMOS transistor is formed after implanting the P-body into the source region of the LDMOS transistor. A fixed thermal cycle associated with forming the gate oxide of the conventional CMOS transistor is not substantially affected by the implanting of the P-body into the source region of the LDMOS transistor.

Abstract: A bipolar junction transistor (BJT) structure and fabrication method are provided in which a doped polysilicon filled trench is utilized to form both the extrinsic base contact region and a vertical field plate. A sacrificial mandrel of dielectric material is formed over regions that will become the BJT active area. This allows the polysilicon filled trench to be extended above the original semiconductor substrate surface. In this way, the base-collector and emitter-base junctions are both self-aligned to the field plate trench. The field plate is utilized to control and shape the electric field in the base-collector depletion region, allowing heavier collector well doping for the same breakdown voltage. This results in improvement in both the breakdown/Ron ratio and the fT*BVcbo product.

Abstract: An apparatus including, in one embodiment, a CMOS device cell including at least first and second CMOS transistors having first and second CMOS transistor doped regions in first and second doped wells, respectively, wherein each of the first and second CMOS transistor doped regions is configured to be biased with a corresponding one of a power supply potential and a ground potential. Such an embodiment also includes a tap cell having first and second tap cell doped regions in the first and second doped wells, respectively, wherein each of the first and second tap cell doped regions is configured to be biased with a different potential relative to the power supply and ground potential.

Abstract: Upon formation of a collector electrode around a base mesa by the lift-off method, a resist film is formed over connection portions between the outer periphery of a region OA1 and a region in which the base mesa is formed, followed by successive formation of gold germanium, nickel and Au in this order over the entire surface of a substrate, so that the resulting stacked film will not become an isolated pattern. Thus, the stacked film over the base mesa is connected to a stacked film at the outer periphery of the region OA1, facilitating peeling of the stacked film over the base mesa. Generation of side etching upon formation of a via hole extending from the back side of the substrate to a backside via electrode is reduced by forming the backside via electrode using a material which hardly reacts with an n-type GaAs layer or n-type InGaAs layer.

Abstract: A semiconductor structure comprises a buried first semiconductor layer of a first doping type, a second semiconductor layer of the first doping type on the buried semiconductor layer, which is less doped than the buried first semiconductor layer, a semiconductor area of a second doping type on the second semiconductor layer, so that a pn junction is formed between the semiconductor area and the second semiconductor layer, and a recess present below the semiconductor area in the buried first semiconductor layer, which comprises a semiconductor material of the first doping type, which can be less doped than the buried first semiconductor layer and has a larger distance to the semiconductor area of the second doping type on the second semiconductor layer, such that the breakdown voltage across the pn junction is higher than if the recess were not provided.

Abstract: A method of forming a lateral bipolar transistor without added mask in CMOS flow including a p-substrate; patterning and n-well implants; pattern and implant pocket implants for core nMOS and MOS; pattern and implants pocket implants I/O nMOS and pMOS; sidewall deposit and etch and then source/drain pattern and implant for nMOS and pMOS. The method includes the steps of forming emitter and collector contacts by implants used in source/drain regions; forming an emitter that includes implants done in core pMOS during core pMOS LDD extender and pocket implant steps and while the collector omits the core pMOS LDD extender and pocket implants; forming a base region below the emitter and collector contacts by the n-well region with said base region going laterally from emitter to collector being the n-well and including pocket implants; and forming base contact by said n-well region and by implants used in nMOS source/drain regions.

Abstract: An EEPROM memory cell uses an emitter polysilicon film for fabricating shallow source/drain regions to increase a breakdown voltage of the wells. The wells are fabricated to be approximately 100 nm (0.1 micrometers (?m)) in depth with a breakdown voltage of approximately 14 volts or more. A typical breakdown voltage of a well in a bipolar process is approximately 10 volts. Due to the increased breakdown voltage achieved, EEPROM memory cells can be produced along with bipolar devices on a single integrated circuit chip and fabricated on a common semiconductor fabrication line.

Abstract: A method of forming a bipolar junction transistor using a CMOS process that includes performing a high voltage deep well and drive-in process in a semiconductor substrate having a predetermined substructure; performing a local oxidation of silicon (LOCOS) process; performing an Nbase and Pbase process on the resulting structure; forming logic N well and P well and annealing the logic wells; forming a poly gate and sequentially forming NMOS/PMOS LDD source/drain; and forming N+/P+ source/drain, annealing the source/drain and sequentially performing a CONT˜PAD process.

Abstract: Silicon on insulator (SOI) field effect transistors (FET) with a shared body contact, a SRAM cell and array including the SOI FETs and the method of forming the SOI FETs. The SRAM cell has a hybrid SOI/bulk structure wherein the source/drain diffusions do not penetrate to the underlying insulator layer, resulting in a FET in the surface of an SOI layer with a body or substrate contact formed at a shared contact. FETs are formed on SOI silicon islands located on a BOX layer and isolated by shallow trench isolation (STI). NFET islands in the SRAM cells include a body contact to a P-type diffusion in the NFET island. Each NFET in the SRAM cells include at least one shallow source/drain diffusion that is shallower than the island thickness. A path remains under the shallow diffusions between NFET channels and the body contact. The P-type body contact diffusion is a deep diffusion, the full thickness of the island. Bit line diffusions shared by SRAM cells on adjacent wordlines may be deep diffusions.

Abstract: A heterojunction bipolar transistor (30) in a silicon-on-insulator (SOI) structure is disclosed. The transistor collector (28), heterojunction base region (20), and intrinsic emitter region (25) are formed in the thin film silicon layer (6) overlying the buried insulator layer (4). A base electrode (10) is formed of polysilicon, and has a polysilicon filament (10f) that extends over the edge of an insulator layer (8) to contact the silicon layer (6). After formation of insulator filaments (12) along the edges of the base electrode (10) and insulator layer (8), the thin film silicon layer (6) is etched through, exposing an edge. An angled ion implantation then implants the heterojunction species, for example germanium and carbon, into the exposed edge of the thin film silicon layer (6), which after anneal forms the heterojunction base region (20).

Abstract: A low-power bipolar transistor is formed to have an intrinsic emitter region with a sub-lithographic width, and an oxide layer that is self aligned to an overlying extrinsic emitter. The small extrinsic emitter region reduces the maximum current that can flow through the transistor, while the self-aligned oxide layer and extrinsic emitter reduces the base-to-emitter junction size and device performance variability across the wafer.

Abstract: A structure and method for a field effect transistor capable of handling high currents, comprises interleaved source and drain diffusion regions with drain diffusion contacts to a first metal level over the drain diffusions only; while a second metal level covers the full width of the device and takes current out of the source in a primarily vertical direction.

Abstract: A semiconductor chip includes a semiconductor substrate having a rectifying contact diffusion and a non-rectifying contact diffusion. A halo diffusion is adjacent the rectifying contact diffusion and no halo diffusion is adjacent the non-rectifying contact diffusion. The rectifying contact diffusion can be a source/drain diffusion of an FET to improve resistance to punch-through. The non-rectifying contact diffusion may be an FET body contact, a lateral diode contact, or a resistor or capacitor contact. Avoiding a halo for non-rectifying contacts reduces series resistance and improves device characteristics. In another embodiment on a chip having devices with halos adjacent diffusions, no halo diffusion is adjacent a rectifying contact diffusion of a lateral diode, significantly improving ideality of the diode and increasing breakdown voltage.

Abstract: A method for manufacturing a programmable chalcogenide fuse within a semiconductor device is disclosed. A resistor is initially formed on a substrate. Then, a chalcogenide fuse is formed on top of the resistor. Finally, a conductive layer is deposited on top of the chalcogenide fuse for providing electrical conduction to the chalcogenide fuse.

Abstract: A semiconductor device which has: a bipolar transistor having a collector region of a second conductivity type formed from the surface of a semiconductor substrate of a first conductivity type, a base region of a first conductivity type formed from the surface of the collector region, and an emitter region of a second conductivity type formed from the surface of the base region; a collector extraction region that is separated by an insulating layer and is formed in the collector region except the base region; a concave portion in the collector extraction region that is formed up to a depth where the collector region has a peak concentration in impurity distribution; and a collector extraction electrode that is connected with the collector region to extract ohmic-connecting to the bottom of the concave portion.

Abstract: A double-diffused metal-oxide-semiconductor (“DMOS”) field-effect transistor (10) with a metal gate (26). A sacrificial gate layer is patterned to provide a self-aligned source mask. The source regions (20) are thus aligned to the gate (26), and the source diffusion provides a slight overlap (28) for good turn-on characteristics and low leakage. The sacrificial gate layer is capable of withstanding the diffusion temperatures of the DMOS process and is selectively etchable. After the high-temperature processing is completed, the sacrificial gate layer is stripped and a metal gate layer is formed over the substrate, filling the volume left by the stripped sacrificial gate material. In one embodiment, a chemical-mechanical polishing technique is used to planarize the metal gate layer.

Abstract: The invention is directed to a returnable plastic crate provided on at least one surface with an ink only label that is removable without destructive treatment of the said surface, said label being adhered to said at least one surface by an activated adhesive layer.

Abstract: In order to form a semiconductor device including a lateral bipolar transistor which is a match in the device performance for a vertical bipolar transistor, an electrically conductive film which is formed by filling a trench reaching a buried oxide film in an SOI substrate with an electrically conductive film is utilized for an emitter and/or a collector, whereby a bipolar transistor is formed through a simple process.

Abstract: A lateral PNP is disclosed in which a substrate of a first conductivity type is used. On top of the substrate a buried region of a second conductivity type is formed. A lightly doped collector region is located above the buried region. The lateral PNP also includes a base region of a second conductivity type formed by a graded channel implant and a well region of a second conductivity type, the well region contacting the base region, the buried region and a base contact. Additionally, there are collector contacts and emitter contacts of a first conductivity type. The lightly doped collector region results in a large Early voltage and the base region provides for a high current gain.

Abstract: A method of forming a dielectric stack device having a plurality of layers comprises the steps of providing a silicon substrate, forming a metal-oxide layer on a silicon oxide layer which is formed on the silicon substrate, and performing an annealing with respect to the metal-oxide layer and the silicon oxide layer until a silicate layer is formed to replace the metal-oxide layer and the silicon oxide layer is removed, wherein the annealing is performed at a temperature between about 800° C. and about 1000° C. for a time period between about 1 second and about 10 minutes. After forming the silicon oxide layer on the silicon substrate, the metal-oxide layer may be deposited on the silicon oxide layer. Alternatively, the metal-oxide layer may be deposited on the silicon substrate, and the silicon oxide layer grows between the metal-oxide layer and the silicon substrate. The metal-based oxide is preferably an Yttrium-based oxide.

Abstract: A collector region is formed on a semiconductor substrate. An emitter electrode, an external base electrode and a gate electrode are formed on the semiconductor substrate. The position of the interface between the gate electrode and the semiconductor substrate is rendered higher than the position of the interface between the external base electrode and the semiconductor substrate. Thus provided is a semiconductor device so improved that dispersion of the withstand voltage of a gate oxide film and dispersion of characteristics such as a threshold voltage and a drain-to-source current are reduced.

Abstract: A novel method of forming a GaAs-based MOS structure comprises ion implantation after oxide formation, and subsequent slow heating and cooling, carried out such that essentially no interfacial defects that are detectable by high resolution transmission electron microscopy are formed. If the MOS structure is a MOS-FET then metal contacts are provided in conventional fashion. A post-metallization anneal can result in FETs that are substantially free of drain current/voltage hysteresis. MOS-FETs made according to the novel method can be produced with high yield and can have significantly increased lifetime, as compared to some prior art GaAs-based MOS-FETs.

Abstract: A low-power high-frequency bipolar transistor is formed to have a small self-aligned base region that reduces the base-to-collector capacitance, and small self-aligned base and emitter contacts that reduce the base-to-emitter capacitance and the base resistance. The base and emitter contacts are formed to have sub-lithographic feature sizes.

Abstract: A method for producing a semiconductor temperature sensor comprises the steps of forming PNP bipolar transistors and PMOS transistors so that a base region of each of the PNP bipolar transistors and a corresponding N-well region of each of the PMOS transistors are formed at the same time, and connecting the PNP bipolar transistors in a Darlington connection.

Abstract: A multi-function semiconductor device is provided. The device includes a bipolar transistor and an FET formed in parallel. A semiconductor substrate is provided on an insulating layer. A source/emitter region and a drain region are formed in the semiconductor substrate and border first opposite sides of a body region therebetween. A gate is formed above the substrate between the source/emitter region and the drain region to form an FET having three terminals including the gate, the source/emitter region, and the drain region. A collector region is formed in the substrate abutting the drain region and extending further under the gate and the drain region. A bipolar transistor having three terminals is formed including a base region, the source/emitter, and the collector region. A shortest distance between the collector region and the source/emitter region defines a base width.

Abstract: The present invention provides a method for integrating the fabrication of a sensor and a high voltage devices. The N conductive type sensor has a P conductive type doped region in the substrate of the sensor active region to effectively reduce the leakage at edges of the field oxide. Furthermore, there are the P conductive type field and the P conductive type well used as isolations for the sensor and these isolations can prevent blooming. Between these isolations, high voltage devices can be simultaneously formed thereon.

Abstract: A method of forming a BiCMOS integrated circuit is provided which comprises the steps of: (a) forming a first portion of a bipolar device in first regions of a substrate; (b) forming a first protective layer over said first regions to protect said first portion of said bipolar devices; (c) forming field effect transistor devices in second regions of said substrate; (d) forming a second protective layer over said second regions of said substrate to protect said field effect transistor devices; (e) removing said first protective layer; (f) forming a second portion of said bipolar devices in said first regions of said substrate; and (g) removing said second protective layer.

Abstract: A method of producing a bipolar transistor includes the step of providing a sacrificial mesa over a layer of SiGe in order to prevent a polysilicon covering layer from forming over a predetermined region of the SiGe layer forming the transistor base. After an etching process removes the sacrificial mesa and the SiGe layer is exposed, an oppositely doped material is applied over top of the SiGe layer to form an emitter. This makes it possible to realize a thin layer of silicon germanium to serve as the transistor base. This method prevents the base layer SiGe from being affected, as it otherwise would be using a conventional double-poly process.

Abstract: A semiconductor device having a bipolar transistor which is capable of high integration, and a semiconductor device in which the bipolar transistor has good characteristic properties. A process for producing said semiconductor device.

Abstract: A semiconductor process is disclosed which forms openings in a dielectric layer through which the emitter region and collector region of lateral bipolar junction transistors are formed. In one embodiment of the invention, the emitter openings for the lateral bipolar junction transistors are first protected by a photoresist layer that is patterned to expose the collector openings for the transistors. A first implant is performed through the exposed windows in the dielectric layer and into the exposed substrate or epitaxial layer therebelow, and then diffused to a suitable depth. The patterned photoresist is then removed to additionally expose the emitter openings, and a second implant is performed, this time into both the collector and the emitter regions, and then diffused to a suitable depth that is shallower than the first implant (used in the collector).

Abstract: An improved structure and method for gated lateral bipolar transistors is provided. The present invention capitalizes on opposing sidewall structures and adjacent conductive sidewall members to conserve available surface space on the semiconductor chips. The conserved surface space allows a higher density of structures per chip. The conductive sidewall members couple to the gate of the gated lateral bipolar transistor and, additionally, to a retrograded, more highly doped bottom layer. The improved structure provides for both metal-oxide semiconductor (MOS) type conduction and bipolar junction transistor (BJT) type conduction beneath the gate of the gated lateral bipolar transistor.

Abstract: After an oxide film has been completely removed from the surface of a substrate by dip etching, the substrate is inserted into a furnace at a temperature as low as about 400° C. to deposit an amorphous silicon film thereon with almost no oxide film existing therebetween. The amorphous silicon film is then patterned into a base electrode and a dopant contained in the base electrode is diffused into the substrate through annealing to form an extrinsic base diffused layer. Thereafter, an intrinsic base diffused layer is formed by ion implantation and an emitter diffused layer is formed by diffusing a dopant from an emitter electrode. Since an oxide film existing between the base electrode and the substrate can be thinner, excessive expansion of the extrinsic base diffused layer due to the diffusion of the dopant can be suppressed.

Abstract: A semiconductor integrated circuit device comprises a multiple-stage amplifier including a plurality of transistors. The multiple-stage amplifier has a first stage comprising a plurality of bipolar transistors each having a single emitter structure. The bipolar transistors are connected parallel to each other. The semiconductor integrated circuit device can easily be designed, is of a self-aligned structure, and has a single transistor size. The semiconductor integrated circuit device may be used as a low-noise, high-power-gain high-frequency amplifier.

Abstract: A structure of a BiCMOS transistor hindering over-etching of source/drain regions of a MOS transistor and a manufacturing method thereof are provided. A polysilicon film that is to be a gate electrode lower layer of a MOS transistor is formed, and thereon, another polysilicon film that is to be a gate electrode upper layer of the MOS transistor as well as to be a base electrode of a bipolar transistor is formed. Thereafter, etching is conducted to form the polysilicon film to be the base electrode of the bipolar transistor and the gate electrode at the same time. Here, an oxide film shown in FIG. 4 serves as a protective film, thereby hindering over-etching of n type and p type wells to be active regions of respective MOS transistors.

Abstract: Disclosed are a method of making GaAs-based enhancement-type MOS-FETs, and articles (e.g., GaAs-based ICs) that comprise such a MOS-FET. The MOS-FETs are planar devices, without etched recess or epitaxial re-growth, with gate oxide that is primarily Ga2O3, and with low midgap interface state density (e.g., at most 1×1011 cm−2 eV−1 at 20° C.). The method involves ion implantation, implant activation in an As-containing atmosphere, surface reconstruction, and in situ deposition of the gate oxide. In preferred embodiments, no processing step subsequent to gate oxide formation is carried out above 300° C. in air, or above about 700° C. in UHV. The method makes possible fabrication of planar enhancement-type MOS-FETs having excellent characteristics, and also makes possible fabrication of complementary MOS-FETs, as well as ICs comprising MOS-FETs and MES-FETs.

Abstract: A method and lateral bipolar transistor structure are achieved, with high current gain, compatible with CMOS processing to form BiCMOS circuits. Making a lateral PNP bipolar involves forming an N− well in a P− doped silicon substrate. A patterned Si3N4 layer is used as an oxidation barrier mask to form field oxide isolation around device areas by the LOCOS method. A polysilicon layer over device areas is patterned to leave portions over the intrinsic base areas of the L-PNP bipolar an implant block-out mask. A buried N− base region is implanted in the substrate under the emitter region. A photoresist mask and the patterned polysilicon layer are used to implant the P++ doped emitter and collector for the L-PNP. The emitter junction depth xj intersects the highly doped N+ buried base region. This N+ doped base under the emitter reduces the current gain of the unwanted (parasitic) vertical PNP portion of the L-PNP bipolar to reduce the current gain of the V-PNP.

Abstract: A new design for a high voltage bipolar transistor is disclosed. Instead of a buried subcollector (which would be N+ in an NPN device), a buried P+ layer is used. The presence of this P+ layer results in pinch-off between itself and the bipolar base. This allows much higher breakdown voltages to be achieved. In particular, the device will not break down at the bottom of the base-collector junction which is the weak spot for conventional devices. A process for manufacturing this device is described. A particular feature of this new process is that the N type epitaxial layer that is grown over the P+ layer is only about half the thickness of its counterpart in the conventional device. The process is fully compatible with conventional BiCMOS processes and has lower cost.

Abstract: In a lateral bipolar transistor, its emitter region, base region, link base region, and so forth, are made in self alignment with side walls of masks by using partly overlapping two mask patterns. Therefore, not relying on the mask alignment accuracy, these regions are made in a precisely controlled positional relation. Thus, the lateral bipolar transistor, thus obtained, is reduced in parasitic resistance of the base and parasitic junction capacitance between the emitter and the base, and alleviated in variance of characteristics caused by fluctuation of the length of a link base region, length of the emitter-base junction and relative positions of the emitter and the collector, and can be manufactured with a high reproducibility.

Abstract: A substantially concentric lateral bipolar transistor and the method of forming same. A base region is disposed about a periphery of an emitter region, and a collector region is disposed about a periphery of the base region to form the concentric lateral bipolar transistor of the invention. A gate overlies the substrate and at least a portion of the base region. At least one electrical contact is formed connecting the base and the gate, although a plurality of contacts may be formed. A further bipolar transistor is formed according to the following method of the invention. A base region is formed in a substrate and a gate region is formed overlying at least a portion of the base region. Emitter and collector terminals are formed on opposed sides of the base region. The gate is used as a mask during first and second ion implants.

Abstract: A method for forming bipolar junction transistor with high gain via formulation of high voltage device in deep submicron process is disclosed. A substrate including a first part, a second part, and a third part is primarily provided; then, a first well in the first part and a second well in the second part are formed. A plurality of field oxide regions are formed on said substrate; subsequently, two third wells are formed in said third part. The following steps are to form a fourth well in said first well in said first part and two fifth wells in said second well in said second part; and to form a first gate on said first part between said two third wells, and a second gate on said second part between said two fifth wells. Next, a first spacer against said first gate and a second spacer against said second gate are formed. Further, first ions are introduced into said first part to serve as a collector region, and into said third part to serve as a first source/drain region.

Abstract: A method and lateral bipolar transistor structure are achieved, with high current gain, compatible with CMOS processing to form BiCMOS circuits. Making a lateral PNP bipolar involves forming an N.sup.- well in a P.sup.- doped silicon substrate. A patterned Si.sub.3 N.sub.4 layer is used as an oxidation barrier mask to form field oxide isolation around device areas by the LOCOS method. A polysilicon layer over device areas is patterned to leave portions over the intrinsic base areas of the L-PNP bipolar an implant block-out mask. A buried N.sup.- base region is implanted in the substrate under the emitter region. A photoresist mask and the patterned polysilicon layer are used to implant the P.sup.++ doped emitter and collector for the L-PNP. The emitter junction depth x.sub.j intersects the highly doped N.sup.+ buried base region. This N.sup.+ doped base under the emitter reduces the current gain of the unwanted (parasitic) vertical PNP portion of the L-PNP bipolar to reduce the current gain of the V-PNP.

Abstract: A semiconductor component includes an asymmetric transistor having two lightly doped drain regions (1300, 1701), a channel region (1702), a source region (1916) located within the channel region (1702), a drain region located outside the channel region (1702), a dielectric structure (1404) located over at least one of the two lightly doped drain regions (1300, 1701), two gate electrodes (1902, 1903) located at opposite sides of the dielectric structure (1404), a drain electrode (1901) overlying the drain region (1915), and a source electrode (1904) overlying the source region (1916). The semiconductor component also includes another transistor having an emitter electrode (122) located between a base electrode (121) and a collector electrode (123) where the base electrode (121) is formed over a dielectric structure (1405).

Abstract: A first polysilicon film which contains phosphorus as an impurity is formed on a semiconductor substrate. A second polysilicon film which is higher in phosphorus concentration than the first polysilicon film is formed on the first polysilicon film. The second polysilicon film is anisotropically etched to expose a surface of the first polysilicon film. Thermal oxidation is then performed. A surface of the first polysilicon film and a surface of the second polysilicon film are oxidized according to their respective oxidization rates depending on their respective phosphorus concentrations. Thus, a semiconductor device in which the size of the gate electrode can be readily controlled and damage to the semiconductor substrate or the like can be suppressed, is obtained.

Abstract: The present invention relates to a method for fabricating an integrated circuit including complementary MOS transistors and a bipolar transistor of NPN type, including the steps of: forming MOS transistors in an epitaxial layer, coating the entire structure with a double protection layer, forming in an opening of this double layer the emitter-base of the bipolar transistor, a specific collector diffusion being formed in the epitaxial layer under the emitter-base region, and reopening the double protection layer at the locations where it is desired to perform silicidations.