Abstract: A dielectric material layer is deposited on gate structures of first and second semiconductor material portions. The dielectric material layer is anisotropically etched to form a first gate spacer on a first semiconductor material portion, while being protected above the second semiconductor material portion. After formation of first raised active regions on the first semiconductor material portion, a dielectric stack of a dielectric oxide liner and a dielectric nitride liner is formed. The dielectric stack is removed over the second semiconductor material portion and a second gate spacer is formed on the second semiconductor material portion, while the dielectric stack protects the first raised active regions. A second gate spacer is formed by anisotropically etching the dielectric material layer over the second semiconductor material portion. The first and second gate spacers have the same composition and thickness. Second raised active regions can be formed on the second semiconductor material portion.

Abstract: In a method for manufacturing a diode, a semiconductor crystal wafer is used to produce a p-n or n-p junction, which extends in planar fashion across the top side of a semiconductor crystal wafer. Separation edges form perpendicularly to the top side of the semiconductor crystal wafer, which edges extend across the p-n or n-p junction. The separation of the semiconductor crystal wafer is achieved in that, starting from a disturbance, a fissure is propagated by local heating and local cooling of the semiconductor crystal wafer. The separation fissure thus formed extends along crystal planes of the semiconductor crystal, which avoids the formation of defects in the area of the p-n or n-p junction.

Abstract: A semiconductor structure and a manufacturing method for the same are provided. The semiconductor structure includes a well region, a dielectric structure, a first doped layer, a second doped layer and a first doped region. The dielectric structure is on the well region. The dielectric structure has a first dielectric sidewall and a second dielectric sidewall opposite to each other. The dielectric structure includes a first dielectric portion and a second dielectric portion, between the first dielectric sidewall and the second dielectric sidewall. The first doped layer is on the well region between the first dielectric portion and the second dielectric portion. The second doped layer is on the first doped layer. The first doped region is in the well region on the first dielectric sidewall.

Abstract: A semiconductor structure and a manufacturing process thereof are disclosed. The semiconductor structure includes a substrate having a first conductive type, a first well having a second conductive type formed in the substrate, a doped region having the second conductive type formed in the first well, a field oxide and a second well having the first conductive type. The doped region has a first net dopant concentration. The field oxide is formed on a surface area of the first well. The second well is disposed underneath the field oxide and connected to a side of the doped region. The second well has a second net dopant concentration smaller than the first net dopant concentration.

Abstract: An improved method for singulation of compound electronic devices is presented. Compound electronic devices are manufactured by combining two or more substrates into an assembly containing multiple devices. Presented are methods for singulation of compound electronic devices using laser processing. The methods presented provide fewer defects such as cracking or chipping of the substrates while minimizing the width of the kerf and maintaining system throughput.

Abstract: Provided are a method of fabricating a semiconductor integrated circuit device and a semiconductor integrated circuit device fabricated using the method. The method includes: forming a mask film, which exposes a portion of a substrate, on the substrate; forming a first buried impurity layer, which contains impurities of a first conductivity type and of a first concentration, in a surface of the exposed portion of the substrate by using the mask film; removing the mask film; forming a second buried impurity layer, which contains impurities of a second conductivity type and of a second concentration, using blank implantation; and forming an epitaxial layer on the substrate having the first and second buried impurity layers, wherein the first concentration is higher than the second concentration.

Abstract: An enhanced shallow trench isolation method for fabricating radiation tolerant integrated circuit devices is disclosed. A layer of pad oxide is first deposited on a semiconductor substrate. A layer of pad nitride is then deposited on the pad oxide layer. A trench is defined within the semiconductor substrate by selectively etching the pad nitride layer, the pad oxide layer, and the semiconductor substrate. Boron ions are then implanted into both the bottom and along the sidewalls of the trench. Subsequently, a trench plug is formed within the trench by depositing an insulating material into the trench and by removing an excess portion of the insulating material. A p-well is implanted to a depth just below the depth of the bottom of the trench. This helps to keep the threshold voltage of the IC device below the trench at a high level, and thereby keep post-radiation leakage low. Then, an electrically neutral species is implanted into the wafer.

Abstract: A semiconductor structure and a manufacturing method for the same are provided. The semiconductor structure includes a well region, a dielectric structure, a first doped layer, a second doped layer and a first doped region. The dielectric structure is on the well region. The dielectric structure has a first dielectric sidewall and a second dielectric sidewall opposite to each other. The dielectric structure includes a first dielectric portion and a second dielectric portion, between the first dielectric sidewall and the second dielectric sidewall. The first doped layer is on the well region between the first dielectric portion and the second dielectric portion. The second doped layer is on the first doped layer. The first doped region is in the well region on the first dielectric sidewall.

Abstract: A photodetector includes a semiconductor substrate having first and second main surfaces opposite to each other. The photodetector includes at least one trench formed in the first main surface and a first anode/cathode region having a first conductivity formed proximate the first main surface and sidewalls of the at least one trench. The photodetector includes a second anode/cathode region proximate the second main surface. The second anode/cathode region has a second conductivity opposite the first conductivity. The at least one trench extends to the second main surface of the semiconductor substrate.

Abstract: A photodetector array includes a semiconductor substrate having opposing first and second main surfaces, a first layer of a first doping concentration proximate the first main surface, and a second layer of a second doping concentration proximate the second main surface. The photodetector includes at least one conductive via formed in the first main surface and an anode/cathode region proximate the first main surface and the at least one conductive via. The via extends to the second main surface. The conductive via is isolated from the semiconductor substrate by a first dielectric material. The anode/cathode region is a second conductivity opposite to the first conductivity. The photodetector includes a doped isolation region of a third doping concentration formed in the first main surface and extending through the first layer of the semiconductor substrate to at least the second layer of the semiconductor substrate.

Abstract: A method for forming a CMOS well structure including forming a plurality of first conductivity type wells over a substrate, each of the plurality of first conductivity type wells formed in a respective opening in a first mask. A cap is formed over each of the first conductivity type wells, and the first mask is removed. Sidewall spacers are formed on sidewalls of each of the first conductivity type wells. A plurality of second conductivity type wells are formed, each of the plurality of second conductivity type wells are formed between respective first conductivity type wells. A plurality of shallow trench isolations are formed between the first conductivity type wells and second conductive type wells. The plurality of first conductivity type wells are formed by a first selective epitaxial growth process, and the plurality of second conductivity type wells are formed by a second selective epitaxial growth process.

Abstract: A first semiconductor region and a second semiconductor region separated by a shallow trench isolation region are formed in a semiconductor substrate. A photoresist is applied and patterned so that the first semiconductor region is exposed, while the second semiconductor region is covered. Depending on the setting of parameters for the location of an edge of the patterned photoresist, the slope of sidewalls of the photoresist, the thickness of the photoresist, and the direction of ion implantation, ions may, or may not, be implanted into the entirety of the surface portion of the first semiconductor region by shading or non-shading of the first semiconductor region. The semiconductor substrate may further comprise a third semiconductor region into which the dopants are implanted irrespective of the shading or non-shading of the first semiconductor region. The selection of shading or non-shading may be changed from substrate to substrate in manufacturing.

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 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 boron ion stream may be used to implant ions, such as boron ions, into the sidewalls of an active area, such as an NFET active area. The boron ion stream has both vertical tilt and horizontal rotation components relative to the sidewalls and/or the silicon device, to provide a better line of sight onto the sidewalls. This may allow components of the silicon device to be moved closer together without unduly reducing the effectiveness of boron doping of NFET active area sidewalls, and provides an improved line of sight of a boron ion stream onto the sidewalls of an NFET active area prior to filling the surrounding trench with STI material.

Abstract: A semiconductor structure is formed comprising a plurality of columns doped with alternating dopants. The columns are separated by trenches, and the dopant is diffused in the doped columns. The trenches are filled with semiconductor material. Other embodiments may be described and claimed.

Abstract: The invention provides a photodiode with an increased charge collection area, laterally spaced from an adjacent isolation region. Dopant ions of a first conductivity type with a first impurity concentration form a region surrounding at least part of the isolation region. These dopant ions are further surrounded by dopant ions of the first conductivity type with a second impurity concentration. The resulting isolation region structure increases the capacitance of the photodiode by allowing the photodiode to possess a greater charge collection region while suppressing the generation of dark current.

Abstract: Certain aspects of a method for reducing noise disturbing at least one signal in an electronic device may comprise shielding a first layer doped with a first dopant from a signaling layer employing a second layer doped with a second dopant. A first signaling component of the signaling layer may be coupled to the second layer and a second signaling component of the signaling layer may be coupled to the second layer. The second layer may be coupled to the first layer, and this reduces the signal disturbing noise in the electronic device. Shielding the first layer from the signaling layer may comprise disposing the second layer between the first layer and the signaling layer. Shielding the first layer from the signaling layer may comprise disposing a deep N-well between the first layer and the signaling layer.

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 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 family of semiconductor devices is formed in a substrate that contains no epitaxial layer. In one embodiment the family includes a 5V CMOS pair, a 12V CMOS pair, a 5V NPN, a 5V PNP, several forms of a lateral trench MOSFET, and a 30V lateral N-channel DMOS. Each of the devices is extremely compact, both laterally and vertically, and can be fully isolated from all other devices in the substrate.

Abstract: A process for forming isolation and active regions, wherein the patterning of an oxidation-barrier active stack is performed separately in the PMOS and NMOS regions. After the active stack is in place, two masking steps are used: one exposes the isolation areas on the NMOS side, for stack etch, channel-stop implant, and silicon recess etch (optional); the other masking step is exactly complementary, and performs the analogous operations on the PMOS side. After these two steps are performed (in either order), an additional nitride layer can optionally be deposited and etched to cover the sidewall of the active stack. Field oxide is then formed, and processing then proceeds in conventional fashion.

Abstract: A mask layer having an opening is formed on a semiconductor substrate. Next, oxygen ions and a first impurity are implanted into the semiconductor substrate using the mask layer as a mask. Then, the mask layer is removed. Next, the oxygen ions are heat treated to react and form an oxide film on the region where the first impurity has been implanted. Then, the oxide film is removed to form a depression in the semiconductor substrate. Next, a gate insulating film and a gate electrode are formed on the depression. Then a second impurity is implanted into the surface of the semiconductor substrate to form a source/drain. An impurity lighter than the oxygen ions and the second impurity is used as the first impurity.

Abstract: The present invention provides an image sensor capable of suppressing the dark current due to crystalline defects occurring at an edge of a field oxide layer and a method for fabricating the same. The present invention provides an image sensor including: a semiconductor substrate; an active area including a photodiode area formed in a predetermined position of the substrate, a floating diffusion area having a smaller area than the photodiode area and a channel area having a bottle-neck structure connecting to the photodiode area and the floating diffusion area; a field area for isolating electrically the active area; a field stop layer being formed beneath the field area by having a wider area than the field area through an expansion towards the active area with a first width; and a gate electrode formed on the substrate by covering the channel area and having one side superposed with a second width on one entire side of the photodiode contacted to the channel area.

Abstract: The present invention provides a method for forming a contact plug in a semiconductor device capable of preventing an increase of contact resistance caused by a decrease in dopant concentration and suppressing diffusions of dopants implanted into the contact. The dopants are doped in a manner to allow the conductive layer to have different doping distributions with respect to a thickness. Particularly, the dopants are doped until reaching a target deposition thickness by gradually increasing a concentration of the dopants from a first concentration to a second concentration for an interval from an initial deposition of the conductive layer to the target deposition thickness, and the second concentration is consistently maintained throughout for an interval from the target deposition thickness to a complete deposition thickness.

Abstract: A method of preventing decreasing threshold voltage of a MOS transistor by formation of shallow trench isolation. Shallow trenches are formed to isolate first active regions and second active regions. The first active regions are located within a core circuit region, while the second active regions are located within a peripheral circuit region. A first ion implantation to form well regions is performed on the first and second active regions, respectively. A second ion implantation is performed on the second active region and edges of the first active regions to form second channel doping regions and to increase ion concentration at the edges of the first active regions, respectively. A third ion implantation is further performed on the first active regions to form first channel doping regions.

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 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: The present disclosure relates to a method for fabricating an image sensor capable of improving dark current characteristics.

Abstract: Aspects of the method for reducing noise in the substrate may comprise doping a substrate with a first dopant and doping a first well disposed on the substrate with a second dopant. The first well may be a deep well. A second well disposed within the first well may be doped with a second dopant. A first transistor having a first transistor channel type and one or more transistor components may be disposed within the second well. A quiet voltage source may be coupled to a body of the first transistor. A third well disposed within the first well may be doped with the first dopant. A second transistor having a second transistor type and one or more transistor components may be disposed within the third well. In this arrangement, disposing the first well between the substrate and the second well may reduce noise in the substrate.

Abstract: A DRAM device having improved charge storage capabilities and methods for providing the same. The device includes an array portion having a plurality of memory cells extending from a semiconductor substrate. Each cell includes a storage element for storing a quantity of charge indicative of the state of the memory cell and a valve element that inhibits the quantity of charge from changing during quiescent periods. The storage elements are disposed adjacent a plurality of storage regions of the substrate and the valve elements are disposed adjacent a plurality of valve regions of the substrate. A plurality of dopant atoms are selectively implanted into the array portion so as to increase a threshold voltage which is required to develop a conducting channel through the valve region. The dopant atoms are disposed mainly throughout the valve regions of the substrate and are substantially absent from the storage regions.

Abstract: The present invention provides an image sensor capable of suppressing the dark current due to crystalline defects occurring at an edge of a field oxide layer and a method for fabricating the same. The present invention provides an image sensor including: a semiconductor substrate; an active area including a photodiode area formed in a predetermined position of the substrate, a floating diffusion area having a smaller area than the photodiode area and a channel area having a bottle-neck structure connecting to the photodiode area and the floating diffusion area; a field area for isolating electrically the active area; a field stop layer being formed beneath the field area by having a wider area than the field area through an expansion towards the active area with a first width; and a gate electrode formed on the substrate by covering the channel area and having one side superposed with a second width on one entire side of the photodiode contacted to the channel area.

Abstract: An electronic device architecture is described comprising a field effect device in an active region 22 of a substrate 10. Channel stop implant regions 28a and 28b are used as isolation structures and are spaced apart from the active region 22 by extension zones 27a and 27b. The spacing is established by using an inner mask layer 20 and an outer mask layer 26 to define the isolation structures.

Abstract: An improved method for forming a self-aligned twin well structure for use in a CMOS semiconductor device including providing a substrate for forming a twin well structure therein; forming an implant masking layer over the substrate to include a process surface said masking layer patterned to expose a first portion of the process surface for implanting ions; subjecting the first portion of the process surface to a first ion implantation process to form a first doped region included in the substrate; forming an implant blocking layer including a material that is selectively etchable to the implant masking layer over the first portion of the process surface; removing the implant masking layer to expose a second portion of the process surface; and, subjecting the second portion of the process surface to a second ion implantation process to form a second doped region disposed adjacent to the first doped region.

Abstract: A process of production of a semiconductor memory device having a memory array including memory cells and a peripheral circuit on one substrate comprising the process of forming an interlayer insulating layer covering the memory array and peripheral circuit; forming the memory cells; exposing a surface of diffusion regions in the peripheral circuit after forming the memory cells; and forming a covering conductive layer on the exposed region of the diffusion regions in peripheral circuit. A semiconductor memory device produced by such a process has memory area having a good data retention due to a low junction leakage in the diffusion regions of the memory cells, whereas it has a high processing speed peripheral circuit due to a low resistance of the diffusion regions of the peripheral circuit.

Abstract: Embodiments of the present invention relate to processes utilized in the manufacturing of a semiconductor device having transistors to achieve high uniformity of threshold voltages. The invention does so by ensuring high uniformity of impurity concentration in the substrate. In one embodiment, a method for manufacturing a semiconductor device having transistors with high uniformity of threshold voltages comprises providing a substrate and a source of impurities, and disposing the substrate and the source of impurities in a first oxygen gas at a first initial temperature and heated to a first target temperature at a first temperature rate to drive the impurities into the substrate. The first initial temperature is sufficiently low to prevent the oxygen from diffusing into the substrate. The substrate is disposed in a second oxygen gas at a second initial temperature and heated to a second target temperature at a second rate to form an oxide layer on the substrate.

Abstract: A method of fabricating different transistor structures with the same mask. A masking layer (214) has two openings (204, 202) that expose two transistor areas (304,302). The width of the second opening (202) is adjusted such that the angled implant is substantially blocked from the second transistor area (302). The angled implant forms pocket regions in the first transistor area (304). The same masking layer (214) may then be used to implant source and drain extension regions in both the first and second transistor areas (304, 302).

Abstract: A method of preventing decreasing threshold voltage of a MOS transistor by formation of shallow trench isolation. Shallow trenches are formed to isolate first active regions and second active regions. The first active regions are located within a core circuit region, while the second active regions are located within a peripheral circuit region. A first ion implantation to form well regions is performed on the first and second active regions, respectively. A second ion implantation is performed on the second active region and edges of the first active regions to form second channel doping regions and to increase ion concentration at the edges of the first active regions, respectively. A third ion implantation is further performed on the first active regions to form first channel doping regions.

Abstract: The present invention provides a method of manufacturing a semiconductor device, and a related method manufacturing an integrated circuit. In one embodiment, the method of manufacturing a semiconductor device includes creating a source/drain region between an electrode and an isolation structure located on a substrate. The method further includes implanting a dopant at a predetermined implant dopant concentration through an opening formed in a channel stop mask and located between the electrode and the isolation structure to form a channel stop between the source/drain region and the isolation structure.

Abstract: A method for incorporating an ion implanted channel stop layer under field isolation for a twin-well CMOS process is described in which the layer is placed directly under the completed field isolation by a blanket boron ion implant over the whole wafer. The channel stop implant follows planarization of the field oxide and is thereby essentially at the same depth in both field and active regions. Subsequently implanted p- and n-wells are formed deeper than the channel stop layer, the n-well implant being of a sufficiently higher dose to over compensate the channel stop layer, thereby removing it's effect from the n-well. A portion of the channel stop implant under the field oxide adjacent the p-well provides effective anti-punchthrough protection with only a small increase in junction capacitance. The method is shown for, and is particularly effective in, processes utilizing shallow trench isolation.

Abstract: A method of manufacturing a low power dissipation semiconductor power device is provided which is easy to perform and suitable for mass production. When a first and second conductivity-type regions are formed on a semiconductor substrate which is selectively irradiated by impurity ions, an excellent super junction is formed by controlling the ion acceleration energy and the width of each irradiated region so that the first and second conductivity-type regions may have a uniform impurity distribution and a uniform width along the direction of irradiation. Another method of manufacturing a low power dissipation semiconductor power device having an excellent super junction is provided which selectively irradiates a collimated neutron beam onto a P+ silicon ingot and forms an N+ region that has a uniform impurity distribution and a uniform width along the direction of irradiation in the P+ silicon ingot.

Abstract: The semiconductor device comprises a semiconductor substrate 10 of a first conduction-type, first wells 20a, 20b of a second conduction-type formed in a first region on the primary surface of the semiconductor substrate 10, a second well 22a formed in a second region on the primary surface of the semiconductor substrate 10 other than the first region, a third well 22b of the first conduction-type formed in the first well, and high-concentration impurity-doped layers 26 of the first conduction-type formed in deep portions of the semiconductor substrate spaced from the primary surface of the semiconductor device in device regions. In the semiconductor device having triple wells according to the present invention, the high-concentration impurity-doped layers are formed in deep portions inside of the device regions. Accordingly, in the case where the wells have a low concentration so that the transistors have a low threshold voltage, the deep portions of the wells can independently have a high concentration.

Abstract: A method for forming enhanced field oxide (FOX) region of low voltage devices in a high voltage process is disclosed. The method includes providing a semiconductor structure comprising a substrate, two field oxide regions on the substrate, a well between the two field oxide regions in the substrate and a silicon nitride layer between the two field oxide regions above the well. As a key step, nitrogen is implanted into the semiconductor structure, and the silicon nitride layer is then removed. Then, a gate oxide layer on the well and silicon oxynitride layer on the field oxide regions are all formed in-situ.

Abstract: A trench isolation structure for high voltage device is provided including a high voltage well, a low voltage well, and trench oxide. The high voltage well is formed first to be the deep junction isolation of isolation region. Next, the trench oxide isolation is formed overlying the high voltage well. Then, the low voltage well with higher concentration is formed underlying the trench oxide by using high energy implant. The isolation structure is a trench oxide(dielectric isolation)-junction isolation structure.

Abstract: An integrated circuit memory device includes a semiconductor substrate having a memory cell area and a select transistor area. A first field insulation layer is included in the memory cell area, and a first channel stop impurity layer is included beneath the first field insulation layer. The first channel stop impurity layer is narrower than the first field insulation area. A second field insulation layer is included in the select transistor area, and a second channel stop impurity layer is included beneath the second field insulation layer. The second channel stop impurity layer is wider than the second field insulation layer. Integrated circuit memory devices are fabricated by defining a memory cell area and a select transistor area of a semiconductor substrate. The memory cell area includes a memory cell active area and a memory cell field area. The select transistor area includes a select transistor active area and a select transistor field area.

Abstract: CMOS devices and process for fabricating low voltage, high voltage, or both low voltage and high voltage CMOS devices are disclosed. According to the process, p-channel stops and source/drain regions of PMOS devices are implanted into a substrate in a single step. Further, gates for both NMOS and PMOS devices are doped with n-type dopant and NMOS gates are self-aligned.

Abstract: A method of forming an isolation structure comprising forming n-type areas and/or p-type areas implanted respectively therein on a first surface of the substrate. A pad oxide film is grown on the substrate first surface covering the p-wells and/or n-wells. A diffusion barrier(s) is deposited on the substrate first surface and a substrate second surface to form an encapsulated structure. The encapsulated structure is annealed to activate the n-type and/or p-type areas. A mask material is applied over the diffusion barrier on the substrate first surface to define active device areas and a dry etch process is used to etch away the unmasked portions of the diffusion barrier. The mask material is stripped and a field oxide is grown on the substrate first surface. A portion of the field oxide and all of the diffusion barrier is removed, resulting in active areas surrounded by a field isolation structure.

Abstract: A method of forming a semiconductor device and the device, the method comprising the steps of providing a silicon substrate of predetermined conductivity type having a layer of silicon oxide with a first mask thereon, implanting a first impurity of the predetermined conductivity type into the substrate in unmasked regions of the substrate, masking the substrate except for a small region immediately adjacent the first mask with a second mask, implanting a second impurity of the predetermined conductivity type into the substrate in the unmasked regions of the substrate to cause some of the impurity to extend in the substrate beneath the first mask, removing the second mask, oxidizing the substrate with the first mask thereon to form a bird's beak extending beneath the first mask with the impurities extending along the bird's beak both beneath and external to the first mask and completing fabrication of a semiconductor device on substrate.

Abstract: A method for forming wells of a semiconductor device, comprising the steps of forming a plurality of field insulating layers on a field region of a semiconductor substrate; forming first impurity regions of a first conductive type at a first depth beneath a surface of the semiconductor substrate; forming first impurity regions of a second conductive type beneath the surface of the semiconductor substrate at a second depth between the field insulating layers; selectively forming second impurity regions of the second conductive type in the first impurity regions of the first conductive type between adjacent field insulating layers; forming second impurity regions of the first conductive type in the first impurity regions of the second conductive type at both sides of the second impurity regions of the second conductive type; and diffusing the first and second impurity regions of the first conductive type and the first and second impurity regions of the second conductive type by a drive-in process to form a firs

Abstract: A method is provided for fabricating a self-aligned edge implanted split-gate flash memory comprising a semiconductor substrate of a first conductivity type having separated first and second regions of a second conductivity type formed therein, the first and second regions defining a substrate channel region therebetween; a floating gate separated from a doped region in the substrate by an oxide layer; a control gate partially overlying and separated by an insulator from said floating gate; said floating gate having thin portions and thick portions; and said thin portions of said floating gate overlying twice doped regions said semiconductor substrate to reduce surface leakage current and improve program speed of the memory cell.

Abstract: A method for forming a semiconductor device comprises the steps of forming an oxide over a silicon layer, forming a blanket first nitride layer over the oxide layer and the silicon layer, and etching the first nitride layer and the oxide layer to form a sidewall from at least the oxide layer and the first nitride layer. Next, a second nitride layer is formed over the sidewall and an oxidizable layer is formed over the second nitride layer. The oxidizable and the second nitride layers are etched to form a spacer from the oxidizable layer from and the second nitride layer, and the oxidizable and the silicon layers are oxidized.

Abstract: A method of fabricating a MOS device with a localized punchthrough stopper. In the process, a dummy layer is employed to define a well for implanting the localized punchthrough stopper. The dummy layer is preferably made of silicon nitride, which has a high etching selectivity with respect to the oxide material forming sidewall spacers of MOS devices. The localized punchthrough stopper is formed at the boundary of the lightly-doped regions and the channel by implanting impurities through the well resulting from the removal of a portion of the dummy layer adjacent to the gate structure.

Abstract: A method of manufacturing a low power dissipation semiconductor power device is provided which is easy to perform and suitable for mass production. When a first and second conductivity-type regions are formed on a semiconductor substrate which is selectively irradiated by impurity ions, an excellent super junction is formed by controlling the ion acceleration energy and the width of each irradiated region so that the first and second conductivity-type regions may have a uniform impurity distribution and a uniform width along the direction of irradiation. Another method of manufacturing a low power dissipation semiconductor power device having an excellent super junction is provided which selectively irradiates a collimated neutron beam onto a P+ silicon ingot and forms an N+ region that has a uniform impurity distribution and a uniform width along the direction of irradiation in the P+ silicon ingot.