Abstract: A semiconductor structure for a high frequency monolithic switch matrix includes a monocrystalline silicon substrate, an amorphous oxide material overlying the monocrystalline silicon substrate, a monocrystalline perovskite oxide material overlying the amorphous oxide material, a monocrystalline compound semiconductor material overlying the monocrystalline perovskite oxide material, and a high frequency semiconductor integrated formed in and over the monocrystalline compound semiconductor material having one or more input ports and one or more output ports. The high frequency semiconductor integrated circuit also includes a high frequency switch circuit that is electrically coupled to a switch driver control circuit that is fabricated on the monocrystalline compound semiconductor material and which provides the DC signals required to control the high frequency circuit.

Abstract: A method and structure for a dynamic random access device which includes a substrate having a trench, a conductor in the trench, a transistor adjacent the trench and a conductive strap electrically connecting the conductor and the transistor, wherein the strap comprises a plurality of strap conductors and the strap has a lower resistance than the conductor. The conductor comprises a first material having a first resistance and the strap comprises a second material different than the first material having a second resistance, wherein the second resistance is lower than the first resistance. The plurality of strap conductors comprises at least two electrically connected strap conductors, and a first strap conductor is adjacent the conductor and a second strap conductor is adjacent the transistor and the first strap conductor has an improved interface with the conductor. The strap comprises a lip strap, wherein the strap forms an L-shape.

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: An electronic power device is integrated monolithically in a semiconductor substrate. The device includes a power region, itself having at least one P/N junction provided therein which comprises a first semiconductor region with a first type of conductivity extending into the substrate from the top surface of the device and being diffused into a second semiconductor region with the opposite conductivity from the first; and an edge protection structure of substantial thickness and limited planar size incorporating at least one trench filled with dielectric material.

Abstract: There is disclosed herein a unique fabrication sequence and the structure of a vertical silicon on insulator (SOI) bipolar transistor integrated into a typical DRAM trench process sequence. A DRAM array utilizing an NFET allows for an integrated bipolar NPN sequence. Similarly, a vertical bipolar PNP device is implemented by changing the array transistor to a PFET. Particularly, a BICMOS device is fabricated in SOI. The bipolar emitter contacts and CMOS diffusion contacts are formed simultaneously of polysilicon plugs. The CMOS diffusion contact is the plug contact from bitline to storage node of a memory cell.

Abstract: A semiconductor device includes the following: a semiconductor substrate of a first conduction type; an intrinsic semiconductor layer of the first conduction type formed on the semiconductor substrate; a first semiconductor layer of a second conduction type formed on the intrinsic semiconductor layer; a first impurity layer of the first conduction type formed in the first semiconductor layer of the second conduction type; and a bipolar transistor and a MIS transistor formed in the first semiconductor layer of the second conduction type. The laminated structure of the semiconductor substrate, the intrinsic semiconductor layer, and the first semiconductor layer provides a diode for photoelectric conversion. A first insulator layer and a second insulator layer are formed respectively in at least a portion below the bipolar transistor and the MIS transistor.

Abstract: The present invention provides a method of forming a metal-oxide-semiconductor (MOS) transistor on a surface of a substrate of a semiconductor wafer. A gate is firstly formed in a predetermined area on the surface of the substrate. A first ion implantation process using group VA elements as dopant is performed thereafter to form a first doped area in portions of the substrate adjacent to either side of the gate. By performing a second ion implantation process immediately after the first ion implantation process using group VIIIA or group IVA elements as dopant, a second doped area is formed in portions of the substrate adjacent to portions of the substrate under the first doped area. After depositing a rapid-thermal chemical vapor deposition (RTCVD) dielectric layer that covers both the substrate and the gate, a spacer on either side of the gate is finally formed by etching back the RTCVD dielectric layer.

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 lateral bipolar transistor with a doped zone of a small lateral width can be obtained by means of a method for manufacturing a lateral bipolar transistor with a collector region and a base region in a SOI wafer slice with an insulating layer, a silicon layer over the insulating layer, with a protective coating of oxide over the silicon layer, with trenches through the protective layer and the silicon layer as far as the insulating layer with substantially lateral walls, which are bounded by substantially lateral faces of the protective coating and the silicon layer, by implanting dopants in the silicon layer, in which the implantation takes place on one of the substantially lateral faces of the silicon layer.

Abstract: The present invention creates a useful BJT by increasing the gain associated with the parasitic BJT on an SOI or bulk type MOSFET. This is done by masking those manufacturing steps that minimize the BJT's beta value, by intentionally increasing the beta value of the BJT, and by driving the base of the BJT with the circuit. Once the gain is increased sufficiently, the BJT may be used productively in the circuit. Because the physical structure of the BJT is already part of the silicon water, its productive use does not require additional space.

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: The invention relates to a method of manufacturing implanted-base, double polysilicon bipolar transistors whose emitter, base and collector are all situated in a single active area. In accordance with the method, first the island isolation (3) defining the active area (4) in the silicon body (1) is provided, which active area forms the collector (5). A first polysilicon layer (6) is deposited on the surface. A first part (6a) of poly I is p-type doped, a second part is n-type doped. By etching, two separate parts are formed from the first poly layer, one part being p-type doped and forming a base terminal (8), the other part being n-type doped and forming a collector terminal (9), said two parts being separated by an intermediate region (16) where the surface of the active area is exposed. The edges of these poly terminals and the exposed parts of the active area are provided with spacers (13, 15) and spacers (14, 16), respectively.

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: A manufacturing method of a semiconductor device which can form high-performance bipolar transistors and high-performance MOS transistors on the same substrate while minimizing increases in the number of manufacturing steps and the number of masks. A base lead-out electrode 105a of an NPN bipolar transistor and the gate 105b of a PMOS transistor can be formed at the same time by using the same material (a polysilicon film 105), and an emitter lead-out electrode 122a of the NPN bipolar transistor and the gate 122b of an NMOS transistor are formed at the same time by using the same material (a polysilicon film 122). Therefore, a surface channel PMOS transistor can be obtained while an increase in the number of manufacturing steps is prevented. As a result, the leak current of the PMOS transistor can be reduced and the threshold voltage Vth can be controlled easily.

Abstract: A process for fabricating a semiconductor device including MOS transistors of low breakdown voltage type and of high breakdown voltage type provided on a semiconductor substrate, the MOS transistor of high breakdown voltage type being operative at a higher voltage than the MOS transistor of low breakdown voltage type and having drift diffusion regions, the process comprises the steps of: forming a LOCOS oxide film on the semiconductor substrate; and performing ion implantation with the use of a single mask having openings respectively defining on the substrate a first region for formation of a first conductivity type MOS transistor of low breakdown voltage type, a second region in which the LOCOS oxide film is formed for isolation of a first conductivity type MOS transistor of high breakdown voltage type, and a third region for formation of a drift diffusion region of a second conductivity type MOS transistor of high breakdown voltage type, so that the first and third regions each have at least two concentrat

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: 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 MOSBJT (Metal Oxide Semiconductor Bipolar Junction Transistor) is formed to have both the higher current drive capability of the BJT and the smaller device area of the scaled down MOSFET. The MOSBJT includes a collector region and an emitter region comprised of a semiconductor material with a first type of dopant. A base region is disposed between the collector region and the emitter region, and the base region is comprised of a semiconductor material with a second type of dopant that is opposite of the first type of dopant. Unlike a conventional BJT, a base terminal of the MOSBJT is comprised of a dielectric structure disposed over the base region and comprised of a gate structure disposed over the dielectric structure. Unlike a conventional MOSFET, the dielectric structure of the MOSBJT is relatively thin such that a tunneling current through the dielectric structure results when a turn-on voltage is applied on the gate structure. This tunneling current is a base current of the MOSBJT.

Abstract: A bipolar transistor device with a large current capacity is formed by connecting a plurality of transistor elements to each other in parallel, each transistor element having a collector layer, a base layer, and an emitter layer formed respectively in a semiconductor substrate. In the bipolar transistor device, the base layers of a plurality of the transistor elements are extended in parallel to each other and those base layers are separated from each other. In each separated base layer, a first base electrode is formed on a part of the base layer which is separated from an emitter junction with the emitter layer, and a second base electrode is formed on another portion of the base layer closer to the emitter junction than the first base electrode. To dispose the base electrodes of a plurality of the transistor elements in parallel to each other, a base wiring is connected to the first base electrodes of those elements electrically.

Abstract: The invention relates to a method for forming a high voltage NMOS transistor together with a low voltage NMOS transistor and a low voltage PMOS transistor, respectively, in an n-well CMOS process by adding solely two additional process steps to a conventional CMOS process: (i) a masking step, and (ii) an ion implantation step for forming a doped channel region for the high voltage MOS transistor in the substrate self-aligned to the edge of the high voltage MOS transistor gate region. The ion implantation is performed through the mask in a direction, which is inclined at an angle to the normal of the substrate surface, to thereby create the doped channel region partly underneath the gate region of the high voltage MOS transistor.

Abstract: A bipolar complementary metal oxide semiconductor device has a c-well fabricated using profile engineering (a multi-energy implant using accurate dosages and energies determined by advance simulation) to provide a higher c-well implant dose while creating a narrow region with relatively low concentration in the collector depletion range to avoid low base-collector breakdown. This achieves a much lower collector series resistance to pull-up a frequency response, a collector sheet resistance which can be as low as 150 &OHgr;/sq., and fT may be increased to 20 GHz or higher.

Abstract: The present invention creates a useful BJT by increasing the gain associated with the parasitic BJT on an SOI or bulk type MOSFET. This is done by masking those manufacturing steps that minimize the BJT's beta value, by intentionally increasing the beta value of the BJT, and by driving the base of the BJT with the circuit. Once the gain is increased sufficiently, the BJT may be used productively in the circuit. Because the physical structure of the BJT is already part of the silicon water, its productive use does not require additional space.

Abstract: Disclosed is a method to provide a new deep trench collar process which reduces encroachment of strap diffusion upon array metal oxide semiconductor field effect transistors (MOSFET's) in semiconductor devices. The invention allows a reduced effective deep trench edge bias at the top of the deep trench, without compromising storage capacitance, by maximizing the distance between the MOSFET gate conductor and the deep trench storage capacitor.

Abstract: A capacitor having variable capacitance for a semiconductor device is formed on a device isolation area. A trench is formed in a semiconductor substrate for device isolation and a device isolating insulating film in which a bottom electrode of the capacitor is buried is formed in the trench. A first dielectric film is formed on the buried bottom electrode, a middle electrode is formed thereon and a second dielectric film and a top electrode are formed on the middle electrode, thereby having a three-layer electrode structure. The capacitor according to the present invention has variable capacitance in accordance with a voltage applied to top, bottom and middle electrodes, respectively.

Abstract: A method of manufacturing a bipolar transistor in a single-crystal silicon substrate of a first conductivity type, including a step of carbon implantation at the substrate surface followed by an anneal step, before forming, by epitaxy, the transistor base in the form of a single-crystal semiconductor multilayer including at least a lower layer, a heavily-doped median layer of the second conductivity type, and an upper layer that contacts a heavily-doped emitter of the first conductivity type.

Abstract: According to one embodiment of the invention, a method for manufacturing bipolar junction transistors includes disposing a first oxide layer between a semiconductor substrate and a base polysilicon layer, forming a dielectric layer outwardly from the base polysilicon layer, and forming an emitter region by removing a portion of the dielectric layer and a portion of the base polysilicon layer. The method further includes removing a portion of the first oxide layer to form undercut regions adjacent the emitter region and to enlarge the emitter region, and forming an oxide pad outwardly from the semiconductor substrate in the emitter region.

Abstract: A method of making high voltage complementary bipolar and BiCMOS devices on a common substrate. The bipolar devices are vertical NPN and PNP transistors having the same structure. The fabrication process utilizes trench isolation and thus is scalable. The process uses two epitaxial silicon layers to form the high voltage NPN collector, with the PNP collector formed from a p-well diffused into the two epitaxial layers. The collector contact resistance is minimized by the use of sinker up/down structures formed at the interface of the two epitaxial layers. The process minimizes the thermal budget and therefore the up diffusion of the NPN and PNP buried layers. This maximizes the breakdown voltage at the collector-emitter junction for a given epitaxial thickness. The epitaxial layers may be doped as required depending upon the specifications for the high voltage NPN device.

Abstract: To program a CMOS memory, an auxiliary bipolar transistor is formed in a P-well adjacent to the P-well of an NMOS device of the CMOS memory, the auxiliary transistor being capable of forcing a large magnitude current through a fusible link, so as to program the electronic state of the CMOS memory cell into a prescribed binary (1/0) condition. A separate implant mask for the emitter region of the auxiliary transistor allows the geometry and impurity concentration profile of the emitter region to be tailored by a deep dual implant, so that the impurity concentration of the emitter region is not decreased, and yields a reduced base width for the auxiliary transistor to provide a relatively large current gain to blow the fuse, while allowing the doping parameters of the source/drain regions of the CMOS structure to be separately established to prevent thyristor latch-up.

Abstract: An enhanced-surface-area conductive layer compatible with high-dielectric constant materials is created by forming a film or layer having at least two phases, at least one of which is electrically conductive. The film may be formed in any convenient manner, such as by chemical vapor deposition techniques, which may be followed by an anneal to better define and/or crystallize the at least two phases. The film may be formed over an underlying conductive layer. At least one of the at least two phases is selectively removed from the film, such as by an etch process that preferentially etches at least one of the at least two phases so as to leave at least a portion of the electrically conductive phase. Ruthenium and ruthenium oxide, both conductive, may be used for the two or more phases. Iridium and its oxide, rhodium and its oxide, and platinum and platinum-rhodium may also be used. A wet etchant comprising ceric ammonium nitrate and acetic acid may be used.

Abstract: An ESD protection circuit that will prevent internal circuits of an integrated circuit is formed on a semiconductor substrate to prevent damage during extreme voltage levels from an ESD voltage source and is connected to an input/output pad. A plurality of drains of multiple MOS FET's is formed within the surface of the semiconductor substrate and are each connected to the input/output pad. A plurality of sources of the multiple MOS FET's is formed within the surface of the semiconductor substrate and are placed at a distance from the plurality of drains and are connected to a ground reference potential. Pairs of the plurality of sources are adjacent to each other. A plurality of isolation regions placed between each source of the pairs of sources and are allowed to float. The multiple MOS FET's have a plurality of parasitic bipolar junction transistors.

Abstract: A method of production of a semiconductor device able to be miniaturized by preventing the decline of the hfe at a low current caused by an increase of a surface recombination current of a bipolar transistor and forming the external base region by self-alignment with respect to emitter polycrystalline silicon in the BiCMOS process. An intrinsic base region of a first semiconductor element is formed, an insulating film having an opening at an emitter formation region of part of the intrinsic base region is formed, and then an emitter electrode of the first semiconductor element and a protective film are formed on an insulating film having the opening. Next, a sidewall insulating film is left on the gate electrode side portion. Simultaneously, the insulating film is removed while partially leaving the emitter region forming-use insulating film under the emitter electrode.

Abstract: The disclosed high voltage device includes a semiconductor substrate, and a first semiconductor layer formed between an underlying first insulating layer and an overlying second insulating layer buried within the semiconductor substrate. The high voltage device includes first and second drift regions formed over the second insulating layer in the semiconductor substrate and spaced apart from each other, an emitter impurity region formed in the first drift region, and a collector impurity region formed in the second drift region. The high voltage device further includes a second semiconductor layer adjacent to and insulated from the collector impurity region, and connected to the first semiconductor layer, and a third semiconductor layer adjacent to and insulated from the emitter impurity region, and connected to the first semiconductor layer.

Abstract: A method of production of a semiconductor device able to be miniaturized by preventing the decline of the hFE at a low current caused by an increase of a surface recombination current of a bipolar transistor and forming an external base region by self-alignment with respect to emitter polycrystalline silicon in the BiCMOS process. An intrinsic base region of a first semiconductor element is formed, then an insulating film having an opening at an emitter formation region of part of the intrinsic base region is formed, and an emitter electrode of the first semiconductor element and a protective film are formed on an insulating film having the opening. Next, a sidewall insulating film is left on gate electrode side portion. Simultaneously, the insulating film is removed while partially leaving the emitter region forming-use insulating film under the emitter electrode.

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: Disclosed is a method of fabricating a semiconductor device in which at least an LDD type insulated-gate field effect transistor and a bipolar transistor are formed on a common base substrate. An insulating layer for forming side walls of an LDD type insulated-gate field effect transistor is formed by a stack of first and second insulating films. An opening is formed in the lower first insulating film at a position in a bipolar transistor forming area, and a single crystal semiconductor layer is formed on a base substrate through the opening. With this configuration, the fabrication steps can be simplified and the reliability of the semiconductor device can be enhanced.

Abstract: A semiconductor device having a capacitor, a bipolar transistor and complementary MOSFETs on a semiconductor substrate, the capacitor being constituted from a first electrode 8, a second electrode 13 separated from the first electrode by an insulating film 11 and a third electrode 15 separated from the second electrode by another insulating film 14 and connected to the first electrode is manufactured; where all electrodes in the capacitor and insulating films between them are formed simultaneously with other manufacturing steps of a bipolar transistor or the MOSFETs. This manufacturing method can produce a semiconductor device such as a Bi-CMOS and the like, which is capable of large scale integration and has a capacitor with a large capacitance but occupying only a small area, with a high efficiency and a low cost.

Abstract: A process for fabricating a BiCMOS device, on a semiconductor substrate, featuring PFET and NFET devices, and an NPN bipolar junction transistor, has been developed. The process features the integration, or the sharing of process steps, used for both the CMOS and bipolar devices, such as the creation of an N type buried layer, used in one region for isolation of PFET devices, and used in a second region, of the semiconductor substrate, as a subcollector region, for the bipolar device. Features of the BiCMOS process include the formation of N well, and P well regions, for CMOS device, as well as the use of an epitaxial silicon layer, to allow optimum bipolar characteristics to be achieved.

Abstract: A method for forming integrated circuit bipolar junction transistors for mixed signal circuits. The implants used to form the well regions of the CMOS circuits 20, 40 form the collector regions of bipolar junction transistors. The CMOS transistor pocket implants form the base region of the bipolar junction transistor, and the CMOS drain extension implants form the emitter region of the bipolar junction transistor.

Abstract: A method of manufacturing a hetero-junction bipolar transistor including a carbon-doped base layer includes the steps of (a) growing a base layer on an underlying layer through chemical vapor deposition, (b) forming at least one semiconductor layer over the base layer, and (c) then subjecting the base layer to thermal annealing at a temperature of 520° C. to 650° C.

Abstract: A method of forming a metal oxide semiconductor (MOS)-controlled bipolar transistor includes tilt angle implanting a first impurity into a semiconductor substrate and implanting a second impurity into the semiconductor substrate to form an emitter and a collector. A corresponding transistor arranged as to combine the large current drive capacity of a bipolar junction transistor (BJT) with the smaller device size of a metal oxide semiconductor field effect transistor (MOSFET) is also provided. The transistor includes a semiconductor structure, a gate located proximate the semiconductor structure, a gate insulator disposed intermediate the semiconductor structure and the gate, a source region located in the semiconductor structure, a drain region located in the semiconductor structure, and a buffer region located in the semiconductor structure proximate the drain region.

Abstract: Form a semiconductor device with dielectric, isolation structures in a top surface of a silicon semiconductor substrate, separating the substrate into emitter, NMOS and PMOS areas. Form a gate oxide layer above the isolation structures on the top surface of the silicon semiconductor substrate. Form a conductive polysilicon layer above the thin silicon oxide layer. Mask the NMOS and PMOS regions of the substrate with an emitter mask having a window over the emitter area of the substrate. Ion implant emitter dopant into a portion of the conductive polysilicon layer over the emitter area of the substrate through the window in the emitter mask. Strip the emitter mask. Anneal the substrate including the thin silicon oxide layer, and the polysilicon layer to drive the dopant into an emitter region in the emitter area in the substrate. Form doped source/drain regions and a base in the emitter area of the substrate.

Abstract: The present invention discloses a method for fabricating isolation trenches applied in BiCMOS processes. The isolation trenches are formed initially by defining an oxide layer formed on a semiconductor substrate. Then an epitaxy layer is formed on the substrate and a polysilicon layer is formed on the oxide layer by selective epitaxial growth (SEG). After forming well regions and a collector region in the epitaxy layer, the polysilicon layer is etched and stopped at the oxide layer such that trenches are formed. Subsequently, an isolating material is filled into the trenches to form isolation trenches. It is noted that the oxide layer definition, the epitaxy layer and the polysilicon layer growth by SEG, and the polysilicon etching processes simplify the process of forming isolation trenches. In addition, the integration of the semiconductor is increased, and the isolating effect is good.

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: In order to define region in which a bipolar transistor is formed, region in which a MOS transistor is formed, and another predetermined region upon a substrate of p-type silicon, the substrate is selectively oxidized (by the LOCOS method). An element isolation region 200-500 nm thick is thereby formed. Then, a silicon oxide film 550 nm thick on the substrate, a silicon nitride film (an oxidation-resistant film) 100-300 nm thick, and a silicon oxide film 5-50 nm thick are formed. Thereafter, a publicly known photolithographic technique is used to form a photoresist pattern having an opening, and then, using the pattern as a mask, the silicon oxide film on the opening is removed. The bipolar transistor and the MOS transistor are thereby integrated in a monolithic manner without degrading the characteristics of the respective elements.

Abstract: On a main surface of a p-type silicon substrate having a bipolar transistor forming region and a MOS transistor forming region, an epitaxial layer is grown and n-type buried layers are formed. After forming a trench penetrating the buried layer, a buried polysilicon layer is formed in the trench. Then, a threshold control layer, a punch-through stopper layer, a channel stopper layer, an n-type well layer and a p-type well layer of each MOSFET are formed. At this point, since the well layer is formed through high energy ion implantation, the n-type buried layer is suppressed from being enlarged, and hence, time required for forming the trench can be shortened. Thus, a practical method of manufacturing a semiconductor device is provided.

Abstract: A SRAM memory cell including an access device formed on a storage device is described. The storage device has at least two stable states that may be used to store information. In operation, the access device is switched ON to allow a signal representing data to be coupled to the storage device. The storage device switches to a state representative of the signal and maintains this state after the access device is switched OFF. When the access device is switched ON, the state of the storage device may be sensed to read the data stored in the storage device. The memory cell may be formed to be unusually compact and has a reduced power supply requirements compared to conventional SRAM memory cells. As a result, a compact and robust SRAM having reduced standby power requirements is realized.

Abstract: The present invention relates to a method for semiconductor manufacturing of one semiconductor circuit, having a multiple of transistors NMOS1, NMOS2, NPN1, NPN2 of one type. The method comprises the steps of arranging a first region 4, 16 on a semiconductor substrate 1, and implementing two transistors of said type, having different sets of characteristics, in said first region 4, 16. The step of implementing said active devices comprises a step of creating a first 6′, 10′ and a second 6″, 10″ subregion within said first region 4, 16, and said step further comprising a step of introducing dopants having different sets of dose parameters, into a first and a second area, respectively, of said first region, said dopants being of a similar type, and a step of annealing said substrate 1 to create said first 6′, 10′ and second 6″, 10″ subregion, respectively, whereby two subregions, having different doping profiles, can be manufactured on a single integrated circuit.

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: The present invention relates to a method of manufacturing a MOS transistor, including the steps of delimiting, using a first resist mask N-type, drain and source implantation areas; removing the first mask and diffusing the implanted dopant; annealing, so that a thicker oxide forms above the source and drain regions than above the central gate insulation area; forming a polysilicon finger above the central gate insulation portion to form the gate of the MOS transistor; and performing a second source/drain implantation.

Abstract: An improved circuit and method for gate-body transistors is provided. The improved circuit and method can accord a faster switching speed and low power consumption. The present invention capitalizes on opposing sidewalls and adjacent conductive sidewall members to conserve available surface space on the semiconductor chips. The gate and body of the transistors are biased to modify the threshold voltage of the transistor (Vt). Additionally, the conductive sidewall members and a gate are biased from a single source. The structure offers performance advantages from both metal-oxide semiconductor (MOS) and bipolar junction transistor (BJT) designs. The device can be used in a variety of applications, digital and analog, wherever a more compact structure with low power consumption and fast response time is needed.