Abstract: A present invention is a method, and resulting device, for fabricating memory cells with an extremely small area and reduced standby current. The small area is accomplished by a judicious use of spacers which allows a tunnel window of a storage device to be fabricated in close proximity to an associated select gate and with a reduced gate width compared to typical devices. The tunnel window is recessed within an upper surface of a substrate. The tunnel window recess is made possible by selective etching of the substrate and oxides covering the substrate. A substantial reduction in the size of a tunnel window means device scaling is possible far beyond what is attainable with standard photolithography. Standby current is reduced significantly by fabricating a select device with complementary material types for the gate compared with the adjacent source/drain regions.

Abstract: A manufacturing method and a device of an EEPROM cell are provided. The method includes the following steps. First, a tunnel layer and an inter-gate dielectric layer are formed over a surface of a substrate respectively, and a doped region is formed in the substrate under the inter-gate dielectric layer and used as a control gate. Thereafter, a floating gate is formed over the inter-gate dielectric layer and the tunnel layer. Thereafter, a source region and a drain region are formed in the substrate beside two sides of the floating gate under the tunnel layer. Especially, the manufacturing method of the memory cell can be integrated with the manufacturing process of high operation voltage component and low operation voltage component.

Abstract: A split gate NAND flash memory structure is formed on a semiconductor substrate of a first conductivity type. The NAND structure comprises a first region of a second conductivity type and a second region of the second conductivity type in the substrate, spaced apart from the first region, thereby defining a channel region therebetween. A plurality of floating gates are spaced apart from one another and each is insulated from the channel region. A plurality of control gates are spaced apart from one another, with each control gate insulated from the channel region. Each of the control gate is between a pair of floating gates and is capacitively coupled to the pair of floating gates. A plurality of select gates are spaced apart from one another, with each select gate insulated from the channel region. Each select gate is between a pair of floating gates.

Abstract: A substrate having a first dielectric layer, a first conductive layer and a second dielectric layer thereon is provided. A part of the second dielectric layer is removed to form a first opening having both ends with a select gate region respectively. The select gate region is constituted by a region with the second dielectric layer and a region without the second dielectric layer. A second conductive layer is formed to cover the second dielectric layer. A cap layer is formed on the second conductive layer. The cap layer, the second conductive layer, the second dielectric layer and the first conductive layer are patterned to form gate structures. The cap layer, the second conductive layer, the second dielectric layer and the first conductive layer between two adjacent select gate regions are removed to form a select gate structure. A doped region is formed in the substrate.

Abstract: Method of manufacturing a semiconductor chip. An array region gate stack is formed on an array region of a substrate and a periphery region gate stack is formed on a periphery region of a substrate. A first dielectric material, a charge-storing material, and a second dielectric material are deposited over the substrate. Portions of the first dielectric material, the charge-storing material, and the second dielectric material are removed to form storage structures on the array region gate stack and on the periphery region gate stack. The storage structures have a generally L-shaped cross-section. A first source/drain region is formed in the array region well. A third dielectric material and a spacer material are deposited over the substrate. Portions of the third dielectric material and the spacer material are removed to form spacers. A second source/drain region is formed in the periphery region well.

Abstract: A memory device may include a number of memory cells, a first interlayer dielectric formed over the memory cells and at least one metal layer formed over the interlayer dielectric. A dielectric layer may be formed over the metal layer. The dielectric layer may represent a cap layer formed at or near an upper surface of the memory device and may be deposited at a relatively low temperature.

Abstract: A method of manufacturing an EEPROM cell includes growing a first oxide layer on a semiconductor substrate; forming a first conductive layer on the first oxide layer; forming a first conductive pattern and a tunneling oxide layer by patterning the first conductive layer and the first oxide layer, the tunneling oxide layer being disposed under the first conductive pattern; forming a gate oxide layer on sidewalls of the first conductive pattern and the substrate and forming a second conductive pattern on both sides of the first conductive pattern; forming a conductive layer for a floating gate by electrically connecting the first conductive pattern to the second conductive pattern; forming a coupling oxide layer on the conductive layer for the floating gate; forming a third conductive layer on the coupling oxide layer; and forming a select transistor and a control transistor by patterning the third conductive layer, the coupling oxide layer, and the conductive layer for the floating gate.

Abstract: A method of forming a gate oxide film for high voltage region of semiconductor devices includes forming patterns on a semiconductor substrate having a high voltage region, thereby exposing only a gate oxide film formation region for high voltage, forming a metal oxidization layer on the entire surface, and performing a process of removing the patterns, thereby forming the metal oxidization layer only in the gate oxide film formation region for high voltage.

Abstract: A substrate having a first dielectric layer, a first conductive layer and a second dielectric layer thereon is provided. A part of the second dielectric layer is removed to form a first opening having both ends with a select gate region respectively. The select gate region is constituted by a region with the second dielectric layer and a region without the second dielectric layer. A second conductive layer is formed to cover the second dielectric layer. A cap layer is formed on the second conductive layer. The cap layer, the second conductive layer, the second dielectric layer and the first conductive layer are patterned to form gate structures. The cap layer, the second conductive layer, the second dielectric layer and the first conductive layer between two adjacent select gate regions are removed to form a select gate structure. A doped region is formed in the substrate.

Abstract: A semiconductor device and fabrication method thereof restrains an amplified current between input voltage Vin and ground voltage Vss, and first and second n-wells are biased into internal voltage sources, whereby the current-voltage characteristic of the input pad becomes stabilized during an open/short checkup of a semiconductor device. The semiconductor device includes a semiconductor substrate having a plurality of device isolation regions, first and second n-wells horizontally spaced from either of the plurality of device isolation regions, a p-channel transistor formed in the second n-well, an input protection transistor horizontally spaced from the first n-well and the device isolation region, on a symmetrical portion by the first n-well to the second n-well, and a guard ring formed between the first n-well and the input protection transistor.

Abstract: Self-aligned split-gate NAND flash memory cell array and process of fabrication in which rows of self-aligned split-gate cells are formed between a bit line diffusion and a common source diffusion in the active area of a substrate. Each cell has control and floating gates which are stacked and self-aligned with each other, and erase and select gates which are split from and self-aligned with the stacked gates, with select gates at both ends of each row which partially overlap the bit line the source diffusions. The channel regions beneath the erase gates are heavily doped to reduce the resistance of the channel between the bit line and source diffusions, and the floating gates are surrounded by the other gates in a manner which provides significantly enhanced high voltage coupling to the floating gates from the other gates.

Abstract: A manufacturing method of a semiconductor device disclosed herein comprises: forming a first protrusion; forming a second protrusion which is higher than the first protrusion; forming a first sidewall on a side surface of the second protrusion; forming a first film so that a surface of the first film is located lower than the second protrusion; forming a mask on a side surface of the first sidewall on a side surface of the second protrusion which protrudes from the surface of the first film; and etching the first film with the mask so as to form a second sidewall on the side surface of the first sidewall on the side surface of the second protrusion but not to form the second sidewall on a side surface of the first protrusion, the second sidewall being formed of the mask and the first film.

Abstract: In a floating gate memory cell including a floating gate separated from an active region by a tunnel isolation region, a first one of the active region and the floating gate comprises a portion that protrudes towards a second one of the active region and the floating gate. In some embodiments, the protruding portion tapers toward the second one of the active region and the floating gate. The tunnel insulation layer may be narrowed at the protruding portion. Protruding portions may be formed on both the floating gate and the active region.

Abstract: An EEPROM device manufacturing method is disclosed. The method includes the steps of oxidation, polysilicon deposition, and etching to form first polysilicon layers of a select transistor and a floating gate electrode. The method also includes a second polysilicon deposition step followed by an etching step to form a logic gate electrode and a control gate electrode at the same time. This method prevents damage to the silicon substrate and reduces the number of process steps compared to conventional manufacturing methods.

Abstract: Semiconductor devices having a dual polysilicon electrode and a method of manufacturing are provided. The semiconductor devices include a first polysilicon layer deposited on a second polysilicon layer. Each polysilicon layer may be doped individually. The method also allows for some semiconductor devices on a wafer to have a single polysilicon wafer and other devices to have a dual polysilicon layer. In one embodiment, the semiconductor devices are utilized to form a memory device wherein the storage capacitors and transistors located in the cell region are formed with a dual polysilicon layer and devices in the periphery region are formed with a single polysilicon layer.

Abstract: A method of fabricating a split gate flash memory device by which stringer generation is prevented. The method includes forming a dielectric layer on an active area of a semiconductor substrate, forming a first gate covered with a cap layer on the dielectric layer, and forming an insulating layer on a sidewall of the first gate. The method also includes forming a dummy spacer over the sidewall of the first gate, the first gate including the cap layer and the insulating layer, and removing the dielectric layer failing to be covered with the dummy spacer and the dummy spacer to form an exposed portion of the substrate. The method further includes forming a gate insulating layer on the exposed portion of the substrate, and forming a second gate overlapping one side of the first gate, wherein a split gate is configured with the first and second gates.

Abstract: In a channel region between the source/drain diffusion layers, impurities of the same conductivity type as the well are doped in an area apart from the diffusion regions. By using as a mask the gate formed in advance, tilted ion implantation in opposite directions is performed to form the diffusion layers and heavily impurity doped region of the same conductivity type as the well in a self-alignment manner relative to the gate.

Abstract: A semiconductor device, which ensures device reliability especially in fine regions and enables great capacitance and high-speed operations, has memory cells including, in a first region of a main surface of a semiconductor substrate, a gate insulating film, a floating gate electrode, an interlayer insulating film, a control gate electrode, and source and drain regions of the second conduction type arranged in a matrix, with a shallow isolation structure for isolating the memory cells. When using a shallow structure buried with an insulating film for element isolation, the isolation withstand voltage in fine regions can be prevented from lowering and the variation in threshold level of selective transistor can be reduced. When the memory cells in a memory mat are divided by means of selective transistors, the disturb resistance of the memory cells can be improved.

Abstract: A flash memory cell and a method for fabricating the same are described. The flash memory cell comprises a substrate, a select gate, a floating gate, a gate dielectric layer, a high-voltage doped region and a source region. The substrate has a first opening thereon and a second opening in the first opening. The select gate is on the sidewall of the first opening, and the floating gate is on the sidewall of the second opening. The gate dielectric layer is between the select/floating gate and the substrate. The high-voltage doped region is in the substrate under the second opening, and the source region is in the substrate beside the first opening. In the method of fabricating the flash memory cell, the select gate and the floating gate are simultaneously formed on the side walls of the first opening and the second opening, respectively.

Abstract: A nonvolatile semiconductor memory includes a trench isolation provided in a semiconductor substrate and an interlayer insulator provided on the semiconductor substrate. The trench isolation defines an active area extending in a first direction at the semiconductor substrate. The interlayer insulator has a wiring trench extending in a second direction intersecting the first direction. A first conductive material layer is provided at the cross-point of the active area and the wiring trench so that it is insulated from the active area. A second conductive material layer is provided in the wiring trench so that it is insulated from the first conductive material layer. A metal layer is provided in the wiring trench so that it is electrically in contact the second conductive material layer.

Abstract: Floating gate transistors and methods of forming the same are described. In one implementation, a floating gate is formed over a substrate. The floating gate has an inner first portion and an outer second portion. Conductivity enhancing impurity is provided in the inner first portion to a greater concentration than conductivity enhancing impurity in the outer second portion. In another implementation, the floating gate is formed from a first layer of conductively doped semiconductive material and a second layer of substantially undoped semiconductive material. In another implementation, the floating gate is formed from a first material having a first average grain size and a second material having a second average grain size which is larger than the first average grain size.

Abstract: A lateral double diffused metal oxide semiconductor (LDMOS) device, and method of fabricating such a device, are provided. The method comprises the steps of: (a) providing a substrate of a first conductivity type; (b) forming within the substrate a well region of a second conductivity type, the well region having a super steep retrograde (SSR) well profile in which a doping concentration changes with depth so as to provide a lighter doping concentration in a surface region of the well region than in a region below the surface region of the well region; (c) forming a gate layer which partly overlies the well region and is insulated from the well region; and (d) forming one of a source region and a drain region in the well region. The presence of the SSR well region provides a lighter surface doping to enable a higher breakdown voltage to be obtained within the LDMOS device, and heavier sub-surface doping to decrease the on-resistance.

Abstract: A negative differential resistance (NDR) field-effect transistor element is disclosed, formed on a silicon-based substrate using conventional MOS manufacturing operations. Methods for improving a variety of NDR characteristics for an NDR element, such as peak-to-valley ratio (PVR), NDR onset voltage (VNDR) and related parameters are also disclosed.

Abstract: A new method to form a floating gate for a flash memory device is achieved. The method comprises forming a gate dielectric layer overlying a substrate. A first conductor layer is deposited overlying the gate dielectric layer. A masking layer is formed overlying the first conductor layer. The masking layer and first conductor layer are etched through. A second conductor layer is deposited overlying the masking layer, the first conductor layer, and the substrate. The second conductor layer is etched down to form spacers on the sidewalls of the first conductor layer and the masking layer. The spacers extend vertically above the top surface of the first conductor layer. The masking layer is etched away to complete said floating gate.

Abstract: A flash memory device and method of manufacturing the same. The flash memory device includes a semiconductor substrate in which a first region where a cell region is formed, a second region where a peripheral region is formed, and a third region formed in the peripheral region at the boundary portion of the cell region and the peripheral region. The device also includes a triple well region formed in the first region and a predetermined region of the third region, an isolation film formed in the first region and having a first depth, an isolation film formed in the second region and having a second depth, which is deeper than the first depth of the isolation film, and a gate oxide film for low voltage and a floating gate, which are stacked on a predetermined region of the first region, a gate oxide film and a gate, which are stacked on a predetermined region of the second region.

Abstract: A method of forming an array of non-volatile memory cells includes forming a plurality of floating gate structures and shaping the plurality of floating gate structures to reduce the width of upper parts of floating gate structures. A first process forms floating gates by etching an upper portion of a polysilicon structure with masking elements in place to shape the floating gate. A second process etches recesses and protrusions in a polysilicon structure prior to etching the structure to form individual floating gates.

Abstract: A non-volatile memory structure including a substrate, a first memory cell row, a first source/drain region, and a second source/drain region is described. The first memory cell row is disposed on the substrate and includes a plurality of memory cells, two select gate structures, and a plurality of doped regions. The select gate structures are respectively disposed on the substrate at one side of the outmost memory cell among the memory cells, and the select gates have a tapered corner at one side far from the memory cells. The doped regions are respectively disposed in the substrate between two memory cells as well as in the substrate between the memory cells and the select gate structures. The first and the second source/drain regions are respectively disposed in the substrate at both sides of the first memory cell row.

Abstract: An integrated circuit is formed by identifying multiple regions, each having transistors that have a gate oxide thickness that differs between the multiple regions. One of the regions includes transistors having a nanocluster layer and another of the regions includes transistors with a thin gate oxide used for logic functions. Formation of the gate oxides of the transistors is sequenced based upon the gate oxide thickness and function of the transistors. Thin gate oxides for at least one region of transistors are formed after the formation of gate oxides for the region including the transistors having the nanocluster layer.

Abstract: A method for forming a nitrided tunnel oxide layer is described. A silicon oxide layer as a tunnel oxide layer is formed on a semiconductor substrate, and a plasma nitridation process is performed to implant nitrogen atoms into the silicon oxide layer. A thermal drive-in process is then performed to diffuse the implanted nitrogen atoms across the silicon oxide layer.

Abstract: Nonvolatile memory devices and methods for fabricating the same are provided. The device includes first and second base patterns disposed under floating and selection gates, respectively, at an active region. A channel region is formed in the active region between the first and second base patterns, and source and drain regions are formed in the active region adjacent to the first and second base patterns, respectively. The method includes forming first and second base patterns on a semiconductor substrate to be separated from each other by a predetermined space. A channel region is formed in the semiconductor substrate between the first and second base patterns. Source and drain regions are formed in the semiconductor substrate adjacent to the reverse side of the channel region on the basis of the first and second base patterns, respectively. A tunnel oxide layer is formed on a predetermined region of the channel region. A memory gate is formed to cover the first base pattern and the tunnel oxide layer.

Abstract: A method of fabricating a nonvolatile memory is provided. The method includes forming a bottom dielectric layer, a charge trapping layer, a top dielectric layer and a conductive layer on the substrate sequentially. Portions of conductive layer, top dielectric layer, charge trapping layer and bottom dielectric layer are removed to form several trenches. An insulation layer is formed in the trenches to form a plurality of isolation structures. A plurality of word lines are formed on the conductive layer and the isolation structures. By using the word lines as a mask, portions of bottom dielectric layer, charge trapping layer, top dielectric layer, conductive layer and isolation structures are removed to form a plurality of devices. The bottom oxide layer has different thickness on the substrate so that these devices can be provided with different performance. These devices serve as memory cells with different character or devices in periphery region.

Abstract: in methods of fabricating a non-volatile memory device having a local silicon-oxide-nitride-oxide-silicon (SONOS) gate structure, a semiconductor substrate having a cell transistor area, a high voltage transistor area, and a low voltage transistor area, is prepared. At least one memory storage pattern defining a cell gate insulating area on the semiconductor substrate within the cell transistor area is formed. An oxidation barrier layer is formed on the semiconductor substrate within the cell gate insulating area. A lower gate insulating layer is formed on the semiconductor substrate within the high voltage transistor area. A conformal upper insulating layer is formed on the memory storage pattern, the oxidation barrier layer, and the lower gate insulating layer. A low voltage gate insulating layer having a thickness which is less than a combined thickness of the upper insulating layer and the lower gate insulating layer is formed on the semiconductor substrate within the low voltage transistor area.

Abstract: A semiconductor device, which ensures device reliability especially in fine regions and enables great capacitance and high-speed operations, has memory cells including, in a first region of a main surface of a semiconductor substrate, a gate insulating film, a floating gate electrode, an interlayer insulating film, a control gate electrode, and source and drain regions of the second conduction type arranged in a matrix, with a shallow isolation structure for isolating the memory cells. When using a shallow structure buried with an insulating film for element isolation, the isolation withstand voltage in fine regions can be prevented from lowering and the variation in threshold level of selective transistors can be reduced. When the memory cells in a memory mat are divided by means of selective transistors, the disturb resistance of the memory cells can be improved.

Abstract: A self-aligned conductive spacer process for fabricating sidewall control gates on both sides of a floating gate for high-speed RAM applications, which can well define dimensions and profiles of the sidewall control gates. A conductive layer is formed on the dielectric layer to cover a floating gate patterned on a semiconductor substrate. Oxide spacer are formed on the conductive layer adjacent to the sidewalls of the floating gate. Performing an anisotropic etch process on the conductive layer and using the oxide spacers as a hard mask, a conductive spacers are self-aligned fabricated at both sides of the floating gate, serving as sidewall control gates.

Abstract: Field-effect transistors, select gates, and select lines have first and second conductive layers separated by an interlayer dielectric layer. A conductive strap is disposed on either side of the first and second conductive layers. Each strap electrically interconnects the first and second conductive layers.

Abstract: A method of fabricating a non-volatile memory based on SONOS is disclosed. By masking the peripheral circuit area with a reverse ONO photoresist layer, the residual ONO layer that is not covered by a gate within the memory array area is etched away to expose the substrate. After the etching of the ONO layer, a channel adjustment doping is carried out subsequently using the reverse ONO photoresist layer as an implant mask, thereby forming lightly doped regions next to the gate within the memory array area. Finally, the reverse ONO photoresist layer is then stripped.

Abstract: A thin layer of single-crystal silicon is produced by forming first trenches in a silicon substrate having (111) orientation; forming narrower second trenches at the bases of the trenches; anisotropically etching lateral channels (4) from the second trenches, until adjacent etch fronts (16) substantially meet; and detaching said layer from the substrate. The trenches may be arranged so that the resultant layer has rows of slots, whit the slots in adjacent rows being mutually offset. Solar cells may be formed on strips (5) between the trenches, having lengths of more than 50 mm, widths of up to 5 mm, and thicknesses of less than 100 microns, and having two electrical contacts on the same face (6) of each strip (5).

Abstract: Provided is related to a method of forming a semiconductor device comprises steps of: providing a semiconductor substrate having a low voltage region and a high voltage region; forming a pad oxide layer and a pad nitride layer in sequence on the semiconductor substrate; removing the pad nitride layer and the pad oxide layer on the semiconductor substrate of the high voltage region, wherein a surface of the semiconductor substrate of the high voltage region is exposed and recessed; forming a sacrificial oxide layer on the surface of the semiconductor substrate of the high voltage region; removing the sacrificial layer; forming a first gate oxide layer on the surface of the semiconductor substrate of the high voltage region; removing the pad oxide layer and the pad nitride layer left on the semiconductor substrate of the low voltage region, wherein a surface of the semiconductor substrate of the low voltage region is exposed and recessed; and forming a second gate oxide layer on the first gate oxide layer and t

Abstract: Gate oxides having different thicknesses are formed on a semiconductor substrate by forming a first gate oxide on the top surface of the substrate, forming a sacrificial hard mask over a selected area of the first gate oxide; and then forming a second gate oxide. A first poly layer may be formed on the first gate oxide, under the hard mask. After the hard mask is removed, a second poly layer may be formed over the second gate oxide and over the first poly layer. This enables the use of high-k dielectric materials, and the first gate oxide can be thinner than the second gate oxide.

Abstract: A method for fabricating a semiconductor memory device in which a logic circuit and a nonvolatile memory are provided on a semiconductor substrate includes the steps of: forming an isolation region; forming a protective film made of an insulating material over the semiconductor substrate in a logic circuit region and a nonvolatile memory region; selectively introducing impurity ions in part of the semiconductor substrate in the logic circuit region; and removing the protective film formed over the logic circuit region. The step of introducing the impurity ions is performed before the step of removing the protective film is performed.

Abstract: Disclosed is a method for manufacturing a flash memory cell. A structure in which a floating gate, an ONO dielectric film and a control gate are stacked is formed by means of a gate mask process and an etch process. After a rapid thermal nitrification process is performed, a re-oxidization process is performed. Therefore, Si-dangling bonding broken during the gate etch process becomes a Si—N bonding structure by means of a rapid thermal nitrification process. As such, as abnormal oxidization occurring at the side of an ONO dielectric film during a re-oxidization process is prohibited, a smiling phenomenon of the ONO dielectric film is prevented.

Abstract: A structure and fabrication method for a gate stack used to define source/drain regions in a semiconductor substrate. The method comprises (a) forming a gate dielectric layer on top of the substrate, (b) forming a gate polysilicon layer on top of the gate dielectric layer, (c) implanting n-type dopants in a top layer of the gate polysilicon layer, (d) etching away portions of the gate polysilicon layer and the gate dielectric layer so as to form a gate stack on the substrate, and (e) thermally oxidizing side walls of the gate stack with the presence of a nitrogen-carrying gas. As a result, a diffusion barrier layer is formed at the same depth in the polysilicon material of the gate stack regardless of the doping concentration. Therefore, the n-type doped region of the gate stack has the same width as that of the undoped region of the gate stack.

Abstract: Methods of fabricating a fin field effect transistor (FinFET) are disclosed. Embodiments of the invention provide methods of fabricating FinFETs by optimizing a method for forming the fin so that a short channel effect is prevented and high integration is achieved. Accordingly, the fin which has a difficulty in its formation using the current photolithography-etching technique may be readily formed.

Abstract: A method of fabricating a non-volatile memory is described. A substrate having a memory cell region and a peripheral circuit region is provided. A plurality of first stacked gate structures is formed on the memory cell region and a stacked structure is formed on the peripheral circuit region. A conductive layer is formed on the substrate to form a plurality of gates between the first stacked gate structures, thereby forming a memory cell row. A plurality of conductive spacers is formed on the sidewalls of the memory cell row and the stacked structure. A patterned mask layer is formed on the substrate to cover at least the memory cell row and the conductive spacers. The stacked structure is patterned to form a plurality of second stacked gate structures on the peripheral circuit region.

Abstract: Method of manufacturing a semiconductor device, including a first baseline technology electronic circuit (1) and a second option technology electronic circuit (2) as functional parts of a system-on-chip, by: manufacturing the first electronic circuit (1) with a first conductive layer (6; 6) that is patterned by subjecting an exposed layer portion thereof to Reactive Ion Etching (RIE); manufacturing the second electronic circuit (2) with a second conductive layer (6; 8) that is patterned by subjecting an exposed layer portion thereof to RIE; providing a tile structure (25; 26); providing the tile structure (25; 26) with at least one dummy conductive layer (6; 8) produced in the same processing step as the second conductive layer (6; 8); and exposing the dummy conductive layer (6; 8), at least partially, to obtain an exposed dummy layer portion, and RIE-etching of that exposed portion too when the second (6; 8) conductive layer is subjected to RIE.

Abstract: A method for forming a split gate flash device is provided. In one embodiment, a semiconductor substrate with a dielectric layer formed thereover is provided. A conductor layer is formed overlying the dielectric layer. A masking layer is deposited overlying the conductor layer. A light sensitive layer is formed overlying the masking layer. The light sensitive layer is patterned and etched to form a pattern of openings therein. The masking layer and the conductor layer are etched according to the pattern of openings in the light sensitive layer. The conductor layer is etched at the outer surface area between the conductor layer and the dielectric layer to form undercuts. The dielectric layer is etched to form a notch profile at the outer surface area between the conductor layer and the dielectric layer and portions of the substrate are etched to form a plurality of trenches. An isolation layer is filled over the plurality of trenches and the masking layer.

Abstract: The present invention is an electronic memory cell and a method for the cell's fabrication comprising a first transistor configured to be coupled to a bit line. The first transistor has an essentially zero voltage drop when activated and is configured to control an operation of the memory cell. A second transistor is configured to operate as a memory transistor and is coupled to the first transistor. The second transistor is further configured to be programmable with a voltage about equal to a voltage on the bit line.

Abstract: The present invention provides a tri-gate lower power device and method for fabricating that tri-gate semiconductor device. The tri-gate device includes a first gate [455] located over a high voltage gate dielectric [465] within a high voltage region [460], a second gate [435] located over a low voltage gate dielectric [445] within a low voltage core region [440] and a third gate [475] located over an intermediate core oxide [485] within an intermediate core region [480]. One method of fabrication includes forming a high voltage gate dielectric layer [465] over a semiconductor substrate [415], implanting a low dose of nitrogen [415a] into the semiconductor substrate [415] in a low voltage core region [440], and forming a core gate dielectric layer [445] over the low voltage core region [440], including forming an intermediate core gate dielectric layer [485] over an intermediate core region [480].

Abstract: A method of fabricating a nonvolatile semiconductor memory including the steps of: sequentially forming a gate insulating layer and a first conductive layer of a floating gate on a semiconductor substrate; depositing an inter-gate insulating layer; forming an opening in a part of the inter-gate insulating layer; depositing a control gate electrode on the inter-gate insulating layer and an exposed portion of the first conductive layer by the opening; and forming the gate electrodes of the memory cell transistors and the gate electrodes of the select transistors by utilizing the etching processes of the control gate electrode, the inter-gate insulating layer and the first conductive layer, wherein the select transistors include at least a part of the exposed portion of the first conductive layer.

Abstract: A nonvolatile memory array is encased in a P-well, and the P-well encased in a deep N-well, the two wells separating the memory array from the integrated circuit substrate and from the other circuitry of the integrated circuit. At the same time the deep N-well is formed for the nonvolatile memory array, deep N-wells are formed for the high-voltage P-channel transistors of the logic circuitry. At the same time the P-well is formed for the nonvolatile memory array, P-wells are formed for the low-voltage N-channel transistors. The memory array contains nonvolatile cells of the type used in the ultra-violet-erasable EPROMs. During erasure, the isolated-well formation allows the source, the drain and the channel of selected cells to be driven to a positive voltage. The isolated well is also driven to a positive voltage equal to, or slightly greater than, the positive voltage applied to the source and drain, thus eliminating the field-plate breakdown-voltage problem.