Abstract: The present invention discloses a method including: providing a substrate; forming a buried oxide layer over the substrate; forming a thin silicon body layer over the buried oxide layer, the thin silicon body layer having a thickness of 3-40 nanometers; forming a pad oxide layer over the thin silicon body layer; forming a silicon nitride layer over the pad oxide layer; forming a photoresist over the silicon nitride layer; forming an opening in the photoresist; removing the silicon nitride layer in the opening; partially or completely removing the pad oxide layer in the opening; removing the photoresist over the silicon nitride layer; forming a field oxide layer from the thin silicon body layer in the opening; removing the silicon nitride layer over the pad oxide layer; and removing the pad oxide layer over the thin silicon body layer.

Abstract: A laterally diffused metal-oxide-semiconductor (LDMOS) device as well as a method of making the same is disclosed. A gate is formed on a semiconductor substrate between a source region and a drain region with one side laterally extending onto a part of a field oxide layer and the opposite side beside the source region. A gate dielectric layer is formed between the gate and the semiconductor substrate, wherein the gate dielectric layer comprises two or more portions having different thicknesses arranged laterally in a way that the thicknesses of the portions gradually increase from one side beside the source doping region to the opposite side bordering the field oxide layer. With such structure, the hot carrier impact is minimized and the gate length can be scaled down to gain Idlin.

Abstract: A method forms a gate conductor over a substrate, and simultaneously forms spacers on sides of the gate conductor and a gate cap on the top of the gate conductor. Isolation regions are formed in the substrate and the method implants an impurity into exposed regions of the substrate not protected by the gate conductor and the spacers to form source and drain regions. The method deposits a mask over the gate conductor, the spacers, and the source and drain regions. The mask is recessed to a level below a top of the gate conductor but above the source and drain regions, such that the spacers are exposed and the source and drain regions are protected by the mask. With the mask in place, the method then safely removes the spacers and the gate cap, without damaging the source/drain regions or the isolation regions (which are protected by the mask). Next, the method removes the mask and then forms silicide regions on the gate conductor and the source and drain regions.

Abstract: A MOSFET device with an isolation structure for a monolithic integration is provided. A P-type MOSFET includes a first N-well disposed in a P-type substrate, a first P-type region disposed in the first N-well, a P+ drain region disposed in the first P-type region, a first source electrode formed with a P+ source region and an N+ contact region. The first N-well surrounds the P+ source region and the N+ contact region. An N-type MOSFET includes a second N-well disposed in a P-type substrate, a second P-type region disposed in the second N-well, an N+drain region disposed in the second N-well, a second source electrode formed with an N+ source region and a P+ contact region. The second P-type region surrounds the N+ source region and the P+ contact region. A plurality of separated P-type regions is disposed in the P-type substrate to provide isolation for transistors.

Abstract: A system and method is disclosed that prevents the formation of a vertical bird's beak structure in the manufacture of a semiconductor device. A polysilicon filled trench is formed in a substrate of the semiconductor device. One or more composite layers are then applied over the trench and the substrate. A mask and etch process is then applied to etch the composite layers adjacent to the polysilicon filled trench. A field oxide process is applied to form field oxide portions in the substrate adjacent to the trench. Because no field oxide is placed over the trench there is no formation of a vertical bird's beak structure. A gate oxide layer is applied and a protection cap is formed over the polysilicon filled trench to protect the trench from unwanted effects of subsequent processing steps.

Abstract: A semiconductor device comprising a field effect transistor having higher breakdown voltage by reducing electric field concentration between the drain region and a gate electrode is provided. A semiconductor device includes, on a silicon substrate, an n-well source region and an n-well drain region, which are formed over a surface layer thereof to be spaced apart from each other; and a gate electrode provided via a gate insulating film, said gate insulating film being formed to extend over said source region and said drain region. Further, LOCOS oxide film 180a is formed in the surface of the silicon substrate in the n-well drain region, and thus the LOCOS oxide film has a constricted portion in the cross sectional view, and the gate electrode is formed to extend across a constricted portion.

Abstract: The present invention provides a method of forming a thin channel MOSFET having low external resistance. The method comprises forming a dummy gate region atop a substrate; implanting oxide forming dopant through said dummy gate to create a localized oxide region in a portion of the substrate aligned to the dummy gate region that thins a channel region; forming source/drain extension regions abutting said channel region; and replacing the dummy gate with a gate conductor.

Abstract: A semiconductor device is provided. The semiconductor device according to the present invention includes a semiconductor substrate, a second insulation layer, a buffer insulation layer adjacent to the second insulation layer, a third insulation layer and transistors. A high voltage device region and a low voltage device region are defined in the semiconductor substrate. The second and third insulation layers are formed in the high and low voltage device regions, respectively. The transistors are formed on the second and third insulation layers, respectively.

Abstract: A semiconductor device includes an active pattern on a substrate, the active pattern including a protrusion with a lower surface on the substrate and an upper surface opposite the lower surface, a width of the protrusion gradually decreasing from the lower surface to the upper surface, the upper surface of the protrusion being sharp and defining a first active region of the active pattern along a first direction, isolation layer patterns on the substrate in recesses at both sides of the active pattern, the isolation layer patterns exposing the first active region, a gate structure on the first active region and on the isolation layer patterns, the gate structure extending along a second direction, the first and second directions being perpendicular to each other, and source/drain regions under the first active region at both sides of the gate structure.

Abstract: Exemplary embodiments provide manufacturing methods for forming a doped region in a semiconductor. Specifically, the doped region can be formed by multiple ion implantation processes using a patterned photoresist (PR) layer as a mask. The patterned PR layer can be formed using a hard-bakeless photolithography process by removing a hard-bake step to improve the profile of the patterned PR layer. The multiple ion implantation processes can be performed in a sequence of, implanting a first dopant species using a high energy; implanting the first dopant species using a reduced energy and an increased implant angle (e.g., about 90 or higher); and implanting a second dopant species using a reduced energy. In various embodiments, the doped region can be used as a double diffused region for LDMOS transistors.

Abstract: An structure for electrically isolating a semiconductor device is formed by implanting dopant into a semiconductor substrate that does not include an epitaxial layer. Following the implant the structure is exposed to a very limited thermal budget so that dopant does not diffuse significantly. As a result, the dimensions of the isolation structure are limited and defined, thereby allowing a higher packing density than obtainable using conventional processes which include the growth of an epitaxial layer and diffusion of the dopants. In one group of embodiments, the isolation structure includes a deep layer and a sidewall and which together form a cup-shaped structure surrounding an enclosed region in which the isolated semiconductor device may be formed. The sidewalls may be formed by a series of pulsed implants at different energies, thereby creating a stack of overlapping implanted regions.

Abstract: A semiconductor device and method of its manufacture is disclosed. The device comprises an active semiconductor region (1A) comprising one or more conductive gates (11) and a contact region (1 B) remote from the active region (1A), typically comprising a field oxide region (3). An insulating layer (17) overlies the remote contact region (1 B) and at least a part of the active semiconductor region (1A) with one or more contact windows (19a) formed therethrough at locations between the conductive gates (11). A metallisation contact pad (23) overlying the insulating layer (17) is provided in the remote contact region (1 B). The metallisation contact pad (23) is contacted with a polysilicon contact strip (15) underlying the insulating layer (17) by a conductive pattern of a plurality of filled contact windows (19b) extending across a substantial part of the area of the contact pad (23). In a preferred embodiment, the pattern is a series of filled parallel trenches.

Abstract: A method of fabricating and a structure of an IC incorporating strained MOSFETs on separated silicon layers are disclosed. N-channel field effect transistors (nFET) and P-channel FETs (pFET) are formed on the separated silicon layers, respectively. Shallow trench insulation (STI) regions adjacent to the nFETs and pFETs thus can be formed to induce different stress to the channel regions of the respective nFETs and pFETs. As a consequence, performance of both the nFETs and the pFETs can be improved by the STI stress. In addition, the area of the IC can also be reduced as the two silicon layers are positioned vertically relative to one another.

Abstract: A method for manufacturing a semiconductor device, includes: a) forming a first semiconductor layer on a semiconductor substrate; b) forming a second semiconductor layer on the first semiconductor layer; c) sequentially etching a part of the second semiconductor layer and a part of the first semiconductor layer so as to form a first groove exposing the first semiconductor layer; d) forming a cavity between the semiconductor substrate and the second semiconductor layer by etching the first semiconductor layer through the first groove under an etching condition in which the first semiconductor layer is more easily etched than the second semiconductor layer; e) forming an embedded oxide film in the cavity; f) etching the embedded oxide film from a lateral surface side thereof so as to form a gap between a peripheral part of the second semiconductor layer and the semiconductor substrate; and g) forming an insulating etching stopper layer in the gap.

Abstract: A method for fabricating a semiconductor device according to the present invention is a method for fabricating a semiconductor device including a substrate layer including a plurality of first regions each having an active region and a plurality of second regions each being provided between adjacent ones of the first region. The fabrication method includes an isolation insulation film formation step of forming an isolation insulation film in each of the second regions so that a surface of the isolation insulation film becomes at the same height as that of a surface of a gate oxide film covering the active region, a peeling layer formation step of forming a peeling layer by ion-implanting hydrogen into the substrate layer after the isolation insulation film formation step, and a separation step of separating part of the substrate layer along the peeling layer.

Abstract: A method for fabricating a semiconductor device is provided, in which drift areas are deeply formed in a silicon substrate even when a drive-in process is performed at a relatively lower temperature for a relatively shorter processing time. Therefore, the defects caused by thermal bird's beaks and the horizontal diffusion of implanted impurities can be effectively suppressed. As a result, the punch-through property and the isolation property of high voltage components of the semiconductor device can be improved. Thus, the chip design size can be reduced.

Abstract: A method for fabricating a semiconductor device is provided. The method includes forming a trench having a predetermined depth in a substrate having an active area and an isolation area by selectively removing the isolation area, forming a well region in the active area of the substrate using the trench as a photo key pattern, forming an isolation layer in the trench by filling the trench with an insulating layer, forming a gate insulating layer on a portion of the well region, forming a gate electrode on the gate insulating layer; and forming a source/drain impurity area on the substrate at both sides of the gate electrode.

Abstract: A transistor of an integrated circuit is provided. A first doped well region is formed in a well layer at a first active region. At least part of the first doped well region is adjacent to a gate electrode of the transistor. A recess is formed in the first doped well region, and the recess preferably has a depth of at least about 500 angstroms. A first isolation portion is formed on an upper surface of the well layer at least partially over an isolation region. A second isolation portion is formed at least partially in the recess of the first doped well region. At least part of the second isolation portion is lower than the first isolation portion. A drain doped region is formed in the recess of the first doped well region. The second isolation portion is located between the gate electrode and the drain doped region.

Abstract: A bi-directional power switch is formed as a monolithic semiconductor device. The power switch has two MOSFETs formed with separate source contacts to the external package and a common drain. The MOSFETs have first and second channel regions formed over a well region above a substrate. A first source is formed in the first channel. A first metal makes electrical contact to the first source. A first gate region is formed over the first channel. A second source region is formed in the second channel. A second metal makes electrical contact to the second source. A second gate region is formed over the second channel. A common drain region is disposed between the first and second gate regions. A local oxidation on silicon region and field implant are formed over the common drain region. The metal contacts are formed in the same plane as a single metal layer.

Abstract: A semiconductor device includes a substrate including a high-voltage transistor area provided with a high-voltage transistor and a low-voltage transistor area provided with a low-voltage transistor; a LOCOS layer provided as a device isolation layer of the high-voltage transistor area; and a shallow-trench isolation layer provided as a device isolation layer of the low-voltage transistor area. Accordingly, a sufficient breakdown voltage level can be provided in a high-voltage transistor area, on-resistance and leakage current can be enhanced, and the chip area in a low-voltage transistor area can be reduced.

Abstract: Fabrication of recessed channel array transistors (RCAT) with a corner gate device includes forming pockets between a semiconductor fin that includes a gate groove and neighboring shallow trench isolations that extend along longs sides of the semiconductor fin. A protection liner covers the semiconductor fin and the trench isolations in a bottom portion of the gate groove and the pockets. An insulator collar is formed in the exposed upper sections of the gate groove and the pockets, wherein a lower edge of the insulator collar corresponds to a lower edge of source/drain regions formed within the semiconductor fin. The protection liner is removed. The bottom portion of the gate groove and the pockets are covered with a gate dielectric and a buried gate conductor layer. The protection liner avoids residuals of polycrystalline silicon between the active area in the semiconductor fin and the insulator collar.

Abstract: Embodiments relate to a semiconductor device in which a first oxide layer may be formed in a channel area under the gate electrode. An electric field loaded on the gate electrode may be reduced when electrons are implanted from the source to the drain, the acceleration of electrons may be reduced, and the electrons implanted in the second oxide layer may be restrained. This may improve the hot-carrier effect, resulting in the increased reliability of the semiconductor device.

Abstract: A method for manufacturing a semiconductor element includes preparing an SOI layer having a transistor forming area and an element isolation area, forming an oxidation-resistant mask layer on the SOI layer, forming a resist mask over the transistor forming area on the oxidation-resistant mask layer, a first etching that etches the oxidation-resistant mask layer using the resist mask so that a predetermined thickness of the oxidation-resistant mask layer remains, a second etching that etches the remaining oxidation-resistant mask layer, using the resist mask and exposing the SOI layer at the element isolation area, and oxidizing the exposed SOI layer using the remaining oxidation-resistant mask layer, to form an element isolation layer. An etching rate during the first etching is higher than during the second etching and a silicon-to-etching selection ratio during the second etching is higher than during the first etching.

Abstract: Microelectronic structures embodying the present invention include a field effect transistor (FET) having highly conductive source/drain extensions. Formation of such highly conductive source/drain extensions includes forming a passivated recess which is back filled by epitaxial deposition of doped material to form the source/drain junctions. The recesses include a laterally extending region that underlies a portion of the gate structure. Such a lateral extension may underlie a sidewall spacer adjacent to the vertical sidewalls of the gate electrode, or may extend further into the channel portion of a FET such that the lateral recess underlies the gate electrode portion of the gate structure. In one embodiment the recess is back filled by an in-situ epitaxial deposition of a bilayer of oppositely doped material. In this way, a very abrupt junction is achieved that provides a relatively low resistance source/drain extension and further provides good off-state subthreshold leakage characteristics.

Abstract: An N-channel transistor includes: an N-type source region, a gate electrode, a P-type body region, an N-type drain offset region, and a drain contact region, which is an N-type drain region. The transistor further includes a gate insulating film that has a thin oxide silicon film (a thin film portion) and a LOCOS film (a thick film portion). The body region has an impurity profile in which the concentration reaches a maximum value near the surface and decreases with distance from the surface. The drain offset region has an impurity profile that has an impurity-concentration peak in a deep portion located a certain depth-extent below the lower face of the LOCOS film.

Abstract: A MOSFET structure and a method of forming it are described. The thickness of a portion of the gate dielectric layer of the MOSFET structure adjacent to the drain region is increased to form a bird's beak structure. The gate-to-drain overlap capacitance is reduced by the bird's beak structure.

Abstract: Methods are provided for semiconductor devices having low contact resistance. The method in accordance with one embodiment of the invention comprises forming an insulating layer overlying a semiconductor substrate, the semiconductor substrate having a device region therein. An opening is formed through the insulating layer to expose a portion of the device region, and the portion of the device region is then electrically contacted by a metallic liner layer. To reduce the resistance of the liner layer and hence the contact, ions of a conductivity determining impurity are implanted into the metallic liner layer. A metal layer is then deposited overlying the metallic liner layer to fill the opening through the insulating layer and to form a conductive plug.

Abstract: The semiconductor device comprises a semiconductor layer 18 formed on an insulation layer 16, a gate electrode 22 formed on the semiconductor layer with a gate insulation film 20 formed therebetween, a source/drain region 24 formed on the semiconductor layer on both sides of the gate electrode, and a semiconductor region 14 buried in the insulation layer 16 in a region below the gate electrode. The surface scattering of the carriers and phonon scattering can be prevented while suppressing the short channel effect. Resultantly the semiconductor device can have high mobility and high speed.

Abstract: A method for fabricating a transistor of a semiconductor device is provided. The method includes: forming device isolation layers in a substrate including a bottom structure, thereby defining an active region; etching the active region to a predetermined depth to form a plurality of recess structures each of which has a flat bottom portion with a critical dimension (CD) larger than that of a top portion; and sequentially forming a gate oxide layer and a metal layer on the recess structures; and patterning the gate oxide layer and the metal layer to form a plurality of gate structures.

Abstract: An electro-optical device includes pixel regions arranged at intersections of a plurality of data lines and a plurality of scanning lines on an element substrate. A sensor element, a sensor signal line for outputting a signal from the sensor element, a common wiring line, and a capacitive-coupling-operation bidirectional diode element are disposed at an end of a region on the element substrate in which the pixel regions are arranged.

Abstract: A metal-oxide-semiconductor (MOS) transistor device is provided. The MOS transistor device includes a substrate, a gate structure, a spacer, a source/drain region and a barrier layer. The gate structure is disposed on the substrate. The gate structure includes a gate and a gate dielectric layer disposed between the gate and the substrate. The spacer is disposed on the sidewall of the gate structure. The source/drain region is disposed in the substrate on two sides of the spacer. The barrier layer is disposed around the source/drain region. The source/drain region and the barrier layer are fabricated using an identical material. However, the doping concentration of the source/drain region is larger than the doping concentration of the barrier layer.

Abstract: A method for forming a high-luminescence Si electroluminescence (EL) phosphor is provided, with an EL device made from the Si phosphor. The method comprises: depositing a silicon-rich oxide (SRO) film, with Si nanocrystals, having a refractive index in the range of 1.5 to 2.1, and a porosity in the range of 5 to 20%; and, post-annealing the SRO film in an oxygen atmosphere. DC-sputtering or PECVD processes can be used to deposit the SRO film. In one aspect the method further comprises: HF buffered oxide etching (BOE) the SRO film; and, re-oxidizing the SRO film, to form a SiO2 layer around the Si nanocrystals in the SRO film. In one aspect, the SRO film is re-oxidized by annealing in an oxygen atmosphere. In this manner, a layer of SiO2 is formed around the Si nanocrystals having a thickness in the range of 1 to 5 nanometers (nm).

Abstract: A method of cleaning a wafer, adapted for a patterned gate structure. The gate structures comprise a gate dielectric layer, a nitrogen-containing barrier layer and a silicon-containing gate layer sequentially stacked over the substrate. The method includes cleaning the substrate with phosphoric acid solution and hydrofluoric acid solution so that silicon nitride residues formed in a reaction between the nitrogen-containing barrier layer and the silicon-containing gate layer can be removed and the amount of pollutants and particles can be reduced. Ultimately, the yield of the process as well as the quality and reliability of the device are improved.

Abstract: A strained silicon semiconductor arrangement with a shallow trench isolation (STI) structure has a strained silicon (Si) layer formed on a silicon germanium (SiGe) layer. A trench extends through the Si layer into the SiGe layer, and sidewall spacers are employed that cover the entirety of the sidewalls within the trench in the SiGe layer. Following STI fill, polish and nitride stripping process steps, further processing can be performed without concern of the SiGe layer being exposed to a silicide formation process.

Abstract: Enhanced silicon-on-insulator (SOI) buried oxide (BOX) structures and methods are provided for implementing enhanced SOI BOX structures. An oxygen implant step is performed from a backside into a thinned silicon substrate layer. An anneal step forms thick buried oxide (BOX) regions from oxygen implants in the silicon substrate layer. The oxygen implant step forms an isolated region near the oxygen implants. A backside implant step selectively dopes the isolated region for forming a backgate for an SOI device being formed including a selected one of anti-fuse (AF) devices, and SOI transistors including PFET and NFET devices.

Abstract: A method of forming a field effect transistor includes forming a channel region within bulk semiconductive material of a semiconductor substrate. Source/drain regions are formed on opposing sides of the channel region. An insulative dielectric region is formed within the bulk semiconductive material proximately beneath at least one of the source/drain regions. A method of forming a field effect transistor includes providing a semiconductor-on-insulator substrate, said substrate comprising a layer of semiconductive material formed over a layer of insulative material. All of a portion of the semiconductive material layer and all of the insulative material layer directly beneath the portion are removed thereby creating a void in the semiconductive material layer and the insulative material layer. Semiconductive channel material is formed within the void. Opposing source/drain regions are provided laterally proximate the channel material. A gate is formed over the channel material.

Abstract: A method of creating ultra tin body fully-depleted SOI MOSFETs in which the SOI thickness changes with gate-length variations thereby minimizing the threshold voltage variations that are typically caused by SOI thickness and gate-length variations is provided. The method of present invention uses a replacement gate process in which nitrogen is implanted to selectively retard oxidation during formation of a recessed channel. A self-limited chemical oxide removal (COR) processing step can be used to improve the control in the recessed channel step. If the channel is doped, the inventive method is designed such that the thickness of the SOI layer is increased with shorter channel length. If the channel is undoped or counter-doped, the inventive method is designed such that the thickness of the SOI layer is decreased with shorter channel length.

Abstract: A method (100) of forming a transistor includes forming a gate structure (108) over a semiconductor body and forming recesses (112) using an isotropic etch using the gate structure as an etch mask. The isotropic etch forms a recess in the semiconductor body that extends laterally in the semiconductor body toward a channel portion of the semiconductor body underlying the gate structure. The method further includes epitaxially growing silicon (114) comprising stress-inducing species in the recesses. The source and drain regions are then implanted (120) in the semiconductor body on opposing sides of the gate structure.

Abstract: In a method of manufacturing a buried channel type transistor, a trench is formed at a surface portion of a substrate. A first and a second threshold voltage control regions are formed at portions of the substrate beneath a bottom face of the trench and adjacent to a sidewall of the trench, respectively. A gate electrode filling the trench is formed. Source/drain regions are formed at portions of the substrate adjacent to the sidewall of the gate electrode. Stopper regions are formed at portions of the substrate beneath the source/drain regions and beneath the first and second threshold voltage control regions, respectively. The buried channel type transistor has a high breakdown voltage between the source/drain regions although a threshold voltage thereof is low.

Abstract: A MOSFET structure in which the channel region is contiguous with the semiconductor substrate while the source and drain junctions are substantially isolated from the substrate, includes a dielectric volume formed adjacent and subjacent to portions of the source and drain regions. In a further aspect of the invention, a process for forming an isolated junction in a bulk semiconductor includes forming a dielectric volume adjacent and subjacent to portions of the source and drain regions.

Abstract: Isotropic etching of sacrificial oxide that is adjacent to a trench fill step in an STI wafer can lead to undesired etching away of a sidewall of the trench fill material (e.g., HDP oxide). A sidewall protecting method conformably coats the trench fill step and sacrificial oxide with an etch-resistant carbohydrate. In one embodiment, conforming ARC fluid is spun-on and hardened. A selective, dry plasma etches the hardened ARC over the sacrificial oxide while leaving intact part of the ARC that adheres to the trench fill sidewall. The remnant sidewall material defines a protective shroud which delays the subsequent isotropic etchant (e.g., wet HF solution) from immediately reaching the sidewall of the trench fill material. The delay length of the shroud can be controlled by tuning the etchback recipe. In one embodiment, the percent oxygen in an O2 plus Cl2 plasma and/or bias power during the plasma etch is used as a tuning parameter.

Abstract: The present invention facilitates semiconductor fabrication by providing methods of fabrication that mitigate leakage and apply strain to channel regions of transistor devices. A semiconductor device having gate structures, channel regions, and active regions is provided (102). Extension regions of a first type of conductivity are formed within the active regions (104). Recesses are then formed within a portion of the active regions (106). Second type recess structures are formed (108) within the recesses, wherein the second type recess structures have a second type of conductivity opposite the first type and are comprised of a strain inducing material. Then, first type recess structures are formed (110) within the recesses and on the second type recess structures, wherein the first type recess structures have the first type of conductivity and are comprised of a strain inducing material.

Abstract: A method for manufacturing the semiconductor device of which a transistor and a MNOS type memory transistor, each of which has a different gate withstand voltage and drain withstand voltage, are included in the same semiconductor layer.

Abstract: This invention provides a semiconductor device with an element isolation implemented by a method of manufacturing a semiconductor device comprising the steps of: forming a pad oxide film 140 and a nitride film 150 sequentially on a silicon layer 130 in an element region S; forming a metal oxide film 180 for generating a fixed electric charge on the nitride film 150 and on the silicon layer 130 in an element isolation region A; forming a field oxide film 160 in the element isolation region A by implementing an oxidation treatment; and removing the metal oxide film 180 on the nitride film 150, the nitride film 150 and the pad oxide film 140. In the semiconductor device, the threshold voltage of a parasitic transistor is made high and prevented from turning on, and the influence of leak current is reduced and the hump characteristic of element is restrained.

Abstract: Disclosed is a method of forming the floating gate in the flash memory device. After the first polysilicon film is deposited on the semiconductor substrate, the trench is formed on the first polysilicon film with the pad nitride film not deposited. The HDP oxide film is then deposited to bury the trench. Next, the HDP oxide film is etched to define a portion where the second polysilicon film will be deposited in advance. The second polysilicon film is then deposited on the entire top surface, thus forming the floating gate. Thus, it is possible to completely remove a moat and an affect on EFH (effective field oxide height), solve a wafer stress by simplified process and a nitride film, and effectively improve the coupling ratio of the flash memory device.

Abstract: A method of forming a field effect transistor may include forming a doped layer at a surface of a semiconductor substrate, and forming a groove through the doped layer at the surface of the semiconductor substrate while maintaining portions of the doped layer on opposite sides of the groove. A gate insulating layer may be formed on a surface of the groove, and a gate electrode may be formed on the gate insulating layer in the groove.

Abstract: Memory integrated circuitry includes an array of memory cells formed over a semiconductive substrate and occupying area thereover, at least some memory cells of the array being formed in lines of active area formed within the semiconductive substrate which are continuous between adjacent memory cells, said adjacent memory cells being isolated from one another relative to the continuous active area formed therebetween by a conductive line formed over said continuous active area between said adjacent memory cells. At least some adjacent lines of continuous active area within the array are isolated from one another by LOCOS field oxide formed therebetween. The respective area consumed by individual memory cells is ideally equal less than 8F2, where “F” is no greater than 0.

Abstract: A new method to form a transistor gate in the manufacture of an integrated circuit device is achieved. The method comprises providing a substrate. A conductor layer is formed overlying the substrate with a dielectric layer therebetween. A masking layer is formed overlying the conductor layer. A resist layer is formed overlying the masking layer. The resist layer is patterned to thereby selectively expose the masking layer. The resist layer exhibits a first spacing between edges of the resist layer. The exposed masking layer is etched through to thereby selectively expose the conductor layer. The etched edges of the masking layer are tapered such that the masking layer exhibits a second spacing between the masking layer edges at the top surface of the conductor layer. The second spacing is less than the first spacing. The exposed conductor layer is etched through to thereby complete a transistor gate.

Abstract: An EPROM structure includes a NMOS transistor integrated with a capacitor. The terminal names of the NMOS transistor follow the conventional nomenclature: drain, source, body and gate. The gate of the NMOS transistor is connected directly and exclusively to one of the capacitor plates. In this configuration, the gate is now referred to as the “floating gate”. The remaining side of the capacitor is referred to as the “control gate”.

Abstract: LDMOS transistor devices and fabrication methods are provided, in which additional dopants are provided to region of a substrate near a thick dielectric between the channel and the drain to reduce device resistance without significantly impacting breakdown voltage. The extra dopants are added by implantation prior to formation of the thick dielectric, such as before oxidizing silicon in a LOCOS process or following trench formation and before filling the trench in an STI process.