Abstract: The semiconductor device having a recess channel transistor includes a device isolation structure formed in a semiconductor substrate to define an active region having a recess region at a lower part of sidewalls thereof and a recess channel region formed in the semiconductor substrate under the active region. A method for fabricating the semiconductor device includes forming a device isolation structure in a semiconductor substrate to form an active region having a recess region at a lower part of sidewalls thereof, a gate insulating film formed over the semiconductor substrate including the recess channel region, and a gate electrode formed over the gate insulating film to fill up the recess channel region.

Abstract: In a power IC device, a surface layer channel CMOS transistor and a trench power MOS transistor are formed on the same chip. In one embodiment, a source region of the trench power MOS transistor is arranged at the same level as a gate electrode of the surface layer channel CMOS transistor. Thus, the power IC device and a method for manufacturing the power IC device are provided for reducing manufacturing cost in the case of forming the trench power MOS transistor and the surface layer channel CMOS transistor on the same chip.

Abstract: A digital logic storage structure includes cross coupled first and second complementary metal oxide semiconductor (CMOS) inverters formed on a semiconductor substrate, the CMOS inverters including a first storage node and a second storage node that is the logical complement of the first storage node; both of the first and second storage nodes each selectively coupled to a deep trench capacitor through a switching transistor, with the switching transistors controlled by a common capacitance switch line coupled to gate conductors thereof; wherein, in a first mode of operation, the switching transistors are rendered nonconductive so as to isolate the deep trench capacitors from the inverter storage nodes and, in a second mode of operation, the switching transistors are rendered conductive so as to couple the deep trench capacitors to their respective storage nodes, thereby providing increased resistance of the storage nodes to single event upsets (SEUs).

Abstract: A vertical transistor forming method includes forming a first pillar above a first source/drain and between second and third pillars, providing a first recess between the first and second pillars and a wider second recess between the first and third pillars, forming a gate insulator over the first pillar, forming a front gate and back gate over opposing sidewalls of the first pillar by depositing a gate conductor material within the first and second recesses and etching the gate conductor material to substantially fill the first recess, forming the back gate, and only partially fill the second recess, forming the front gate, forming a second source/drain elevationally above the first source/drain, and providing a transistor channel in the first pillar. The channel is operationally associated with the first and second sources/drains and with the front and back gates to form a vertical transistor configured to exhibit a floating body effect.

Abstract: A method of fabricating a MOSFET provides a plurality of nanowire-shaped channels in a self-aligned manner. According to the method, a first material layer and a semiconductor layer are sequentially formed on a semiconductor substrate. A first mask layer pattern is formed on the semiconductor layer, and recess regions are formed using the first mask layer pattern as an etch mask. A first reduced mask layer pattern is formed, and a filling material layer is formed on the surface of the substrate. A pair of second mask layer patterns are formed, and a first opening is formed. Then, the filling material layer is etched to form a second opening, the exposed first material layer is removed to expose the semiconductor layer, and a gate insulation layer and a gate electrode layer enclosing the exposed semiconductor layer are formed.

Abstract: Embodiments disclosed herein include methods in which a pair of openings are formed into semiconductor material, with the openings being spaced from one another by a segment of the semiconductor material. Liners are formed along sidewalls of the openings, and then semiconductor material is isotropically etched from bottoms of the openings to merge the openings and thereby completely undercut the segment of semiconductor material. Embodiments disclosed herein may be utilized in forming SOI constructions, and in forming field effect transistors having transistor gates entirely surrounding channel regions. Embodiments disclosed herein also include semiconductor constructions having transistor gates surrounding channel regions, as well as constructions in which insulative material entirely separates an upper semiconductor material from a lower semiconductor material.

Abstract: First and second transistors are formed adjacent to each other. Both transistors have gate sidewall spacers removed. A stressor layer is formed overlying the first and second transistors. Stress in the stressor layer that overlies the first transistor is modified. Stress in the stressor layer that overlies the second transistor is permanently transferred to a channel of the second transistor. The stressor layer is removed except adjacent the gate electrode sidewalls of the first transistor and the second transistor where the stressor layer is used as gate sidewall spacers. Electrical contact to electrodes of the first transistor and the second transistor is made while using the gate sidewall spacers for determining a physical boundary of current electrodes of the first and second transistors. Subsequently formed first and a second stressors are positioned close to transistor channels of the first and second transistors.

Abstract: A method for fabricating a vertical channel transistor device is provided. An opening is formed in a dielectric stack comprised of a pad nitride layer and a pad oxide layer. A plurality of epitaxial silicon growth and dry etching processes are carried out to form drain, vertical channel and source in the opening. Subsequently, sidewall gate dielectric and sidewall gate electrode are formed on the vertical channel. The present invention is suited for dynamic random access memory (DRAM) devices, particularly suited for very high-density trench-capacitor DRAM devices.

Abstract: The semiconductor device includes an active region, a recess, a Fin-type channel region, a gate insulating film, and a gate electrode. The active region is defined by a device isolation structure formed in a semiconductor substrate. The recess is formed by etching the active region and its neighboring device isolation structure using an island-type recess gate mask as an etching mask. The Fin-type channel region is formed on the semiconductor substrate at a lower part of the recess. The gate insulating film is formed over the active region including the Fin-type channel region and the recess. The gate electrode is formed over the gate insulating film to fill up the Fin-type channel region and the recess.

Abstract: A method of manufacturing a semiconductor device includes forming on a semiconductor substrate, a plurality of multi-layered structures each including a first semiconductor layer and a second semiconductor layer that is deposited over the first semiconductor layer and has an etching rate smaller than the etching rate of the first semiconductor layer, forming a first trench through the first semiconductor layer and the second semiconductor layer, forming a support body on sidewalls of the first semiconductor layer and the second semiconductor layer in the first trench, forming a second trench that exposes through the second semiconductor layer, etching the first semiconductor layer via the second trench selectively, to form under the second semiconductor layer, a cavity resulting from removal of the first semiconductor layer, forming a buried insulating layer that is buried in the cavity, exposing a side surface of the deposited second semiconductor layer, forming a gate insulating film on the exposed side sur

Abstract: A vertical transistor forming method includes forming a first pillar above a first source/drain and between second and third pillars, providing a first recess between the first and second pillars and a wider second recess between the first and third pillars, forming a gate insulator over the first pillar, forming a front gate and back gate over opposing sidewalls of the first pillar by depositing a gate conductor material within the first and second recesses and etching the gate conductor material to substantially fill the first recess, forming the back gate, and only partially fill the second recess, forming the front gate, forming a second source/drain elevationally above the first source/drain, and providing a transistor channel in the first pillar. The channel is operationally associated with the first and second sources/drains and with the front and back gates to form a vertical transistor configured to exhibit a floating body effect.

Abstract: A multi-bridge-channel MOSFET (MBCFET) may be formed by forming a stacked structure on a substrate that includes channel layers and interchannel layers interposed between the channel layers. Trenches are formed by selectively etching the stacked structure. The trenches run across the stacked structure parallel to each other and separate a first stacked portion including channel patterns and interchannel patterns from second stacked portions including channel and interchannel layers remaining on both sides of the first stacked portion. First source and drain regions are grown using selective epitaxial growth. The first source and drain regions fill the trenches and connect to second source and drain regions defined by the second stacked portions. Marginal sections of the interchannel patterns of the first stacked portion are selectively exposed. Through tunnels are formed by selectively removing the interchannel patterns of the first stacked portion beginning with the exposed marginal sections.

Abstract: A semiconductor wafer is provided with a wiring structure, and semiconductor chip positions arranged in rows and columns. The semiconductor wafer has at least one coating (6) as a self-supporting dimensionally stable substrate layer (4), and/or as a wiring structure composed of conductive, high-temperature-resistant material. The coating material (6) of the substrate layer (4) and/or of the wiring structure has a ternary carbide and/or a ternary nitride and/or carbon.

Abstract: A circuit board with an built-in electronic component according to the present invention includes an insulating layer, a first wiring pattern provided on a first main surface of the insulating layer, a second wiring pattern provided on a second main surface different from the first main surface of the insulating layer, and an electronic component such as a semiconductor chip or the like provided in an internal portion of the insulating layer. The electronic component includes a first external connection terminal formed on a first surface and a second external connection terminal formed on a second surface different from the first surface. The first external connection terminal is connected electrically to the first wiring pattern, and the second external connection terminal is connected electrically to the second wiring pattern.

Abstract: A semiconductor device (20, 21, 22), including: a channel region (4) of a first conductivity type formed at a surface layer portion of a semiconductor substrate (1); a source region (25) of a second conductivity type which is different from the first conductivity type, the source region (25) being formed at a rim of a trench (17) having a depth sufficient to penetrate through the channel region (4); a drain region (2) of the second conductivity type formed at a region adjacent to a bottom of the trench (17); a gate insulating film (13) formed along an inner side wall of the trench (17); a gate electrode (26, 36) arranged in the trench (17) so as to be opposed to the channel region (4) with the gate insulating film (13) interposed therebetween; a conductive layer (37, 40, 40a, 40b) formed in the trench (17) so as to be nearer to the drain region (2) than the gate electrode (26, 36); and an insulating layer (15) surrounding the conductive layer (37, 40, 40a, 40b) to electrically insulate the conductive layer (3

Abstract: In a method of fabricating a fin field effect transistor having a plurality of protruding channels, the fin field effect transistor is formed by forming a dummy gate pattern on a first hard mask pattern and a first insulating layer on a semiconductor substrate having an active region pattern, forming a source and drain region in a portion of the active region pattern, forming a plurality of vertically protruding channels between the source and drain region, forming a gate dielectric layer on the active region pattern having the plurality of protruding channels, and forming a gate electrode on the gate dielectric layer.

Abstract: A single transistor vertical memory gain cell with long data retention times. The memory cell is formed from a silicon carbide substrate to take advantage of the higher band gap energy of silicon carbide as compared to silicon. The silicon carbide provides much lower thermally dependent leakage currents which enables significantly longer refresh intervals. In certain applications, the cell is effectively non-volatile provided appropriate gate bias is maintained. N-type source and drain regions are provided along with a pillar vertically extending from a substrate, which are both p-type doped. A floating body region is defined in the pillar which serves as the body of an access transistor as well as a body storage capacitor. The cell provides high volumetric efficiency with corresponding high cell density as well as relatively fast read times.

Abstract: A functional device including on a substrate a first electrode layer, a second electrode layer opposed to the first electrode layer, a functional layer disposed between the first electrode layer and the second electrode layer and a wiring for applying a potential to the first electrode layer or the second electrode layer, wherein there are provided a first insulating layer formed on the second electrode layer in such an arrangement that the side wall of the functional layer is covered and a contact hole formed in the first insulating layer extending to the second electrode layer in which the wiring for connecting the second electrode layer is provided.

Abstract: Memory devices, arrays, and strings are described that facilitate the use of NROM memory cells in NAND architecture memory strings, arrays, and devices. NROM NAND architecture memory embodiments of the present invention include NROM memory cells in high density vertical NAND architecture arrays or strings facilitating the use of reduced feature size process techniques. These NAND architecture vertical NROM memory cell strings allow for an improved high density memory devices or arrays that can take advantage of the feature sizes semiconductor fabrication processes are generally capable of and yet do not suffer from charge separation issues in multi-bit NROM cells.

Abstract: A memory cell for a memory array in a folded bit line configuration. The memory cell includes an access transistor formed in a pillar of single crystal semiconductor material. The access transistor has first and second source/drain regions and a body region that are vertically aligned. The access transistor further includes a gate coupled to a wordline disposed adjacent to the body region. The memory cell also includes a passing wordline that is separated from the gate by an insulator for coupling to other memory cells adjacent to the memory cell. The memory cell also includes a trench capacitor. The trench capacitor includes a first plate that is formed integral with the first source/drain region of the access transistor. The trench capacitor also includes a second plate that is disposed adjacent to the first plate and separated from the first plate by a gate oxide.

Abstract: Memory elements, switching elements, and peripheral circuits to constitute a nonvolatile memory are integrally formed on a substrate by using TFTs. Since semiconductor active layers of memory element TFTs are thinner than those of other TFTs, impact ionization easily occurs in channel regions of the memory element TFTs. This enables low-voltage write/erase operations to be performed on the memory elements, and hence the memory elements are less prone to deteriorate. Therefore, a nonvolatile memory capable of miniaturization can be provided.

Abstract: An architecture for creating multiple operating voltage MOSFETs. Generally, an integrated circuit structure includes a semiconductor area with a major surface formed along a plane and first and second spaced-apart doped regions formed in the surface. A third doped region forming a channel of different conductivity type than the first region is positioned over the first region. A fourth doped region of a different conductivity and forming a channel is positioned over the second region. The process of creating the gate structure for each of the two transistors allows for the formation of oxide layers of different thickness between the two transistors. The transistors are therefore capable of operating at different operating voltages (including different threshold voltages). Each transistor further includes fifth and sixth layers positioned respectively over the third and fourth regions and having an opposite conductivity type with respect to the third and fourth regions.

Abstract: A vertical gain memory cell including an n-channel metal-oxide semiconductor field-effect transistor (MOSFET) and p-channel junction field-effect transistor (JFET) transistors formed in a vertical pillar of semiconductor material is provided. The body portion of the p-channel transistor is coupled to a second source/drain region of the MOSFET which serves as the gate for the JFET. The second source/drain region of the MOSFET is additionally coupled to a charge storage node. Together the second source/drain region and charge storage node provide a bias to the body of the JFET that varies as a function of the data stored by the memory cell. A non destructive read operation is achieved. The stored charge is sensed indirectly in that the stored charge modulates the conductivity of the JFET so that the JFET has a first turn-on threshold for a stored logic “1” condition and a second turn-on threshold for a stored logic “0” condition.

Abstract: A method is used to make a bit selectable device having nanotube memory elements. A structure having at least two transistors is provided, each with a drain and a source with a defined channel region therebetween, each transistor further including a gate over said channel. A trench is formed between one of the source and drain of a first transistor and one of the source and drain of a second transistor. An electrical communication path is formed in the trench between one of the source and drain of a first transistor and one of the source and drain of a second transistor. A defined pattern of nanotube fabric is provided over at least a horizontal portion of the structure and extending into the trench. An electrode is provided in the trench.

Abstract: A method for fabricating organic light-emitting diodes (OLEDs) and OLED displays using screen-printing, where a first electrode, at least one organic material, and a second electrode are formed on a substrate and at least one of the first and second electrodes and the at least one organic material is screen printed by positioning a screen with openings forming a pattern above a substrate and depositing a material onto the substrate through the openings. Exemplary embodiments include fabricating the electrodes and/or the at least one organic material as continuous layers or uniform, discrete blocks on the substrate and fabricating red, green, and blue OLEDs on the same substrate, which are then placed in OLED displays.

Abstract: A method for integrated processing of a high Voltage MOSFET device and a split gate MOSFET device whereby a novel method is provided to form the split gate device and the high voltage MOSFET device in parallel processing steps including an oxide formation step whereby an oxide spacer layer in a split gate device is formed using about the same overall thermal budget while forming in parallel a thick gate oxide for a an embedded high voltage MOSFET device.

Abstract: A carbon nanotube memory cell for an integrated circuit wherein a chamber is constructed in a layer of a dielectric material such as silicon nitride down to a first electrical contact. This chamber is filled with polysilicon. A layer of a carbon nanotube mat or ribbon is formed over the silicon nitride layer and the chamber. A dielectric material, such as an oxide layer, is formed over the nanotube strips and patterned to form an upper chamber down to the ribbon layer to permit the ribbon to move into the upper chamber or into the lower chamber. The upper chamber is then filled with polysilicon. A silicon nitride layer is formed over the oxide layer and a contact opening is formed down to the ribbon and filled with tungsten that is then patterned to form metal lines. Any exposed silicon nitride is removed. A polysilicon layer is formed over the tungsten lines and anisotropically etched to remove polysilicon on the horizontal surfaces but leave polysilicon sidewall spacers.

Abstract: A leadframe for use with integrated circuit chips comprising a leadframe base made of aluminum or aluminum alloy having a surface layer of zinc; a first layer of nickel on said zinc layer, said first nickel layer deposited to be compatible with aluminum and zinc; a layer of an alloy of nickel and a noble metal on said first nickel layer; a second layer of nickel on said alloy layer, said second nickel layer deposited to be suitable for lead bending and solder attachment; and an outermost layer of noble metal, whereby said leadframe is suitable for solder attachment to other parts, for wire bonding, and for corrosion protection.

Abstract: First and second metal foil layers are laminated on opposite surfaces of a first insulating layer to form a first board. Then, the first and second metal foil layers are formed into predetermined conductor patterns respectively. Then, second and third insulating layers of second and third boards formed separately from the first board are laminated on the first and second metal foil layers through first and second adhesive layers respectively. Then, a thin layer portion is removed and thick layer portions are formed into predetermined conductor patterns respectively in third and fourth metal foil layers of the second and third boards.

Abstract: A method of forming medium breakdown voltage vertical transistors (11) and lateral transistors (12, 13) on the same substrate (14) provides for optimizing the epitaxial layer (16) for the lateral transistors (12, 13). The vertical transistor (11) is formed in a well (18) that has a lower resistivity than the epitaxial layer (16) to provide the required low on-resistance for the vertical power transistor (11).

Abstract: An improved TOL process with a partial lithography-assisted sacrifcial oxide strip to prevent arsenic out-diffusion from polysilicon studs during gate oxidation. The invention prevents arsenic out-diffusion during gate oxidation from polysilicon studs by completely covering polysilicon studs with an oxide layer during gate oxidation, therby mantaining nitrogen amounts in the thin gate oxide regions, and hence, maintaining gate oxide thickness and avoiding any increase in Vt's for thin gate devices.

Abstract: A shorter gate length FET for very large scale integrated circuit chips is achieved by providing a wafer with multiple threshold voltages. Multiple threshold voltages are developed by combining multiple work function gate materials. The gate materials are geometrically aligned in a predetermined pattern so that each gate material is adjacent to other gate materials. A patterned linear array embodiment is developed for a multiple threshold voltage design. The method of forming a multiple threshold voltage FET requires disposing different gate materials in aligned trenches within a semiconductor wafer, wherein each gate material represents a separate work function. The gate materials are arranged to be in close proximity to one another to accommodate small gate length designs.

Abstract: A method for controlling a semiconductor processing apparatus including a vacuum processing chamber, a plasma apparatus for generating plasma inside the vacuum processing chamber, and a process controller for controlling a process by holding a process recipe including plasma cleaning of inside of the vacuum processing chamber constant, comprises the steps of detecting process abnormality of the process on the basis of sensor data detected by sensors arranged in the semiconductor processing apparatus, and executing a recovery step for removing deposition deposited inside the vacuum processing chamber when abnormality is detected.

Abstract: An integrated circuit includes a first conductive layer, an insulator layer disposed on the first conductive layer, and a second conductive layer disposed on the insulator layer. A first fuse is disposed in the first conductive layer and provides a first signal, and a second fuse is disposed in the second conductive layer in alignment with the first fuse and provides a second signal.

Abstract: Disclosed are a semiconductor integrated circuit device and a method of manufacturing the same capable of realizing the two-level gate insulator process for the DRAM without increasing the number of manufacturing steps and that of photomasks. After forming a gate electrode of a MISFET which constitutes a memory cell in a memory array region on a semiconductor substrate, the substrate is subjected to thermal treatment (re-oxidation process). At this time, since bird's beak of the thick gate insulating film formed below the sidewall portion of the gate electrode penetrates into the center of the gate electrode, a gate insulating film thicker than the gate insulating film before the re-oxidation process is formed just below the center of the gate electrode.

Abstract: A memory cell structure for a folded bit line memory array of a dynamic random access memory device includes buried bit and word lines, with the access transistors being formed as a vertical structure on the bit lines. Isolation trenches extend orthogonally to the bit lines between the access transistors of adjacent memory cells, and a pair of word lines are located in each of the isolation trenches. The word lines are oriented vertically widthwise in the trench and are adapted to gate alternate access transistors, so that both an active and a passing word line can be contained within each memory cell to provide a folded bit line architecture. The memory cell has a surface area that is approximately 4 F2, where F is a minimum feature size. Also disclosed are processes for fabricating the DRAM cell using bulk silicon or a silicon on insulator processing techniques.

Abstract: The invention relates to the protection of devices in a monolithic chip fabricated from an epitaxial wafer, such as a wafer for a Group III-V compound semiconductor or a wafer for a Group IV compound semiconductor. Devices fabricated from Group III-V compound semiconductors offer higher speed and better isolation than comparable devices from silicon semiconductors. Semiconductor devices can be permanently damaged when exposed to an undesired voltage transient such as electrostatic discharge (ESD). However, conventional techniques developed for silicon devices are not compatible with processing techniques for Group III-V compound semiconductors, such as gallium arsenide (GaAs). Embodiments of the invention advantageously include transient voltage protection circuits that are relatively efficiently and reliably manufactured to protect sensitive devices from undesired voltage transients.

Abstract: A process for fabricating a CMOS integrated circuit with vertical MOSFET devices is disclosed. In the process, at least three layers of material are formed sequentially on a semiconductor substrate. The three layers are arranged such that the second layer is interposed between the first and third layers. The second layer is sacrificial, that is, the layer is completely removed during subsequent processing. The thickness of the second layer defines the physical gate length of the vertical MOSFET devices. After the at least three layers of material are formed on the substrate, the resulting structure is selectively doped to form an n-type region and a p-type region in the structure. Windows or trenches are formed in the layers in both the n-type region and the p-type region. The windows terminate at the surface of the silicon substrate in which one of either a source or drain region is formed. The windows or trenches are then filled with a semiconductor material.

Abstract: The invention includes a DRAM array having a structure therein which includes a first material separated from a second material by an intervening insulative material. The first material is doped to at least 1×1017 atoms/cm3 with n-type and p-type dopant. The invention also includes a semiconductor construction in which a doped material is over a segment of a substrate. The doped material has a first type majority dopant therein, and is electrically connected with an electrical ground. A pair of conductively-doped diffusion regions are adjacent the segment, and spaced from one another by at least a portion of the segment. The conductively-doped diffusion regions have a second type majority dopant therein. The invention also encompasses methods of forming semiconductor constructions.

Abstract: An MOS power device a substrate comprises an upper layer having an upper surface and an underlying drain region, a well region of a first conductance type disposed in the upper layer over the drain region, and a plurality of spaced apart buried gates, each of which comprises a trench that extends from the upper surface of the upper layer through the well region into the drain region. Each trench comprises an insulating material lining its surface, a conductive material filling its lower portion to a selected level substantially below the upper surface of the upper layer, and an insulating material substantially filling the remainder of the trench. A plurality of highly doped source regions of a second conductance type are disposed in the upper layer adjacent the upper portion of each trench, each source region extending from the upper surface to a depth in the upper layer selected to provide overlap between the source regions and the conductive material in the trenches.

Abstract: A vertical power transistor trench-gate semiconductor device has an active area (100) accommodating transistor cells and an inactive area (200) accommodating a gate electrode (25) (FIG. 6). While an n-type layer (14) suitable for drain regions still extends to the semiconductor body surface (10a), gate material (11) is deposited in silicon dioxide insulated (17) trenches (20) and planarised to the top of the trenches (20) in the active (100) and inactive (200) areas. Implantation steps then provide p-type channel-accommodating body regions (15A) in the active area (100) and p-type regions (15B) in the inactive area (200), and then source regions (13) in the active area (100). Further gate material (111) is then provided extending from the gate material (11) in the inactive area (200) and onto a top surface insulating layer (17B) for contact with the gate electrode (25).

Abstract: A method of forming an HF power device. The method includes forming a semiconductor layer as a first conductive type on a semiconductor substrate; etching the semiconductor layer forming a first trench; doping an impurity in the neighborhood of the first trench forming a first impurity layer; burying a conduction film into the first trench; etching the semiconductor layer forming a second trench; forming a field oxide film buried into the second trench; forming a gate electrode on a surface of the semiconductor layer; forming a source on the surface of the semiconductor layer; forming a drain area on the surface of the semiconductor layer; forming an LLD area on the surface of the semiconductor layer between the drain area and the gate electrode; forming a first metal electrode; and forming a second metal electrode electrically connected to the LDD area.

Abstract: The present invention provides a double gated transistor and a method for forming the same that results in improved device performance and density. The preferred embodiment of the present invention provides a double gated transistor with asymmetric gate doping, where one of the double gates is doped degenerately n-type and the other degenerately p-type. By doping one of the gates n-type, and the other p-type, the threshold voltage of the resulting device is improved. Additionally, the preferred transistor design uses an asymmetric structure that results in reduced gate-to-drain and gate-to-source capacitance. In particular, dimensions of the weak gate, the gate that has a workfunction less attractive to the channel carriers, are reduced such that the weak gate does not overlap the source/drain regions of the transistor. In contrast the strong gate, the gate having a workfunction that causes the inversion layer to form adjacent to it, is formed to slightly overlap the source/drain regions.

Abstract: A process forms a power semiconductor device with reduced input capacitance and improved switching speed. A substrate with an epitaxial has an oxide layer patterned to form a narrow terraced gate. A gate oxide layer is formed on the upper surface of the epitaxial layer. A layer of polysilicon is deposited on the narrow terraced gate oxide region and the gate oxide layer. The polysilicon layer is anisotropically etched to form polysilicon spacers abutting each of the two side surfaces of the narrow terraced gate region. A p-type dopant is implanted through the gate oxide layer and the polysilicon spacers and is driven in to form P-well regions in the epitaxial layer. A source mask is formed and an n-type dopant is implanted through the gate oxide layer and the polysilicon spacers. It is driven in to form N+ source regions in the P-well regions.

Abstract: A memory system having electromechanical memory cells and decoders is disclosed. A decoder circuit selects at least one of the memory cells of an array of such cells. Each cell in the array is a crossbar junction at least one element of which is a nanotube or a nanotube ribbon. The decoder circuit is constructed of crossbar junctions at least one element of each junction being a nanotube or a nanotube ribbon.

Abstract: An electronic power device is integrated monolithically in a semiconductor substrate. The device has a first power region and a second region, each region comprising at least one P/N junction formed of a first semiconductor region with a first type of conductivity, which first semiconductor region extends through the substrate from the top surface of the device and is diffused into a second semiconductor region with the opposite conductivity from the first. The device also includes an interface structure between the two regions, of substantial thickness and limited planar size, comprising at least one trench filled with dielectric material.

Abstract: A semiconductor rectifying device which emulates the characteristics of a low forward voltage drop Schottky diode and which is capable of a variety of electrical characteristics from less than 1 A to greater than 1000 A current with adjustable breakdown voltage. The manufacturing process provides for uniformity and controllability of operating parameters, high yield, and readily variable device sizes. The device includes a semiconductor body with a guard ring on one surface to define a device region in which are optionally formed a plurality of conductive plugs. Between the guard ring and the conductive plugs are a plurality of source/drain, gate and channel elements which function with the underlying substrate in forming a MOS transistor.

Abstract: A semiconductor device and a method for forming the semiconductor device, include forming a mandrel, forming spacer wordline conductors on sidewalls of the mandrel, separating, by using a trim mask, adjacent spacer wordline conductors, and providing a contact area to contact alternating ones of pairs of the spacer wordline conductors.

Abstract: A memory cell containing double-gated vertical metal oxide semiconductor field effect transistors (MOSFETs) and isolation regions such as shallow trench isolation, STI, regions that are self-aligned to the wordlines and bitlines of the cell are provided. The inventive memory cell substantially eliminates the backgating problem and floating well effects that are typically present in prior art memory cells. A method of fabricating the inventive memory cell is also provided.

Abstract: A halo implant (42, 44) for an MOS transistor (10) is formed in a semiconductor substrate (12) at a shallow implant angle, relative to normal to the substrate surface (29). A polysilicon gate structure (32, 33) is formed over a gate oxide (28) and then a hard mask (70), such as a TEOS-generated layer of silicon oxide, is deposited on an upper surface (68) of the gate. The mask is etched with a blanket anisotropic etch to form a cap-shaped mask (72). The shape of the cap causes the dopant for the halo implant to penetrate to a depth which follows the contour of the cap. Thus, halo implants may be formed which extend under the gate structure without the need for large angle implants and resultant shadowing problems caused by adjacent devices.