Abstract: In one aspect, a lateral MOS device is provided. The lateral MOS device includes a gate electrode disposed at least partially in a gate trench to apply a voltage to a channel region, and a drain electrode spaced from the gate electrode, and in electrical communication with a drift region having a boundary with a lower end of the channel region. The device includes a gate dielectric layer in contact with the gate electrode, and disposed between the gate electrode and the drain electrode. The channel region is adjacent to a substantially vertical wall of the gate trench. The device includes a field plate contacting the gate electrode and configured to increase a breakdown voltage of the device.

Abstract: A process for manufacturing a MOS device includes forming a semiconductor layer having a first type of conductivity; forming an insulated gate structure having an electrode region (25), above the semiconductor layer (23); forming body regions having a second type of conductivity, within the semiconductor layer, laterally and partially underneath the insulated gate structure; forming source regions having the first type of conductivity, within the body regions; and forming a first enrichment region, in a surface portion of the semiconductor layer underneath the insulated gate structure. The first enrichment region has the first type of conductivity and is set at a distance from the body regions. In order to form the first enrichment region, a first enrichment window is defined within the insulated gate structure, and first dopant species of the first type of conductivity are introduced through the first enrichment window and in a way self-aligned thereto.

Abstract: Methods of forming an array of memory cells and memory cells that have pillars. Individual pillars can have a semiconductor post formed of a bulk semiconductor material and a sacrificial cap on the semiconductor post. Source regions can be between columns of the pillars, and gate lines extend along a column of pillars and are spaced apart from corresponding source regions. Each gate line surrounds a portion of the semiconductor posts along a column of pillars. The sacrificial cap structure can be selectively removed to thereby form self-aligned openings that expose a top portion of corresponding semiconductor posts. Individual drain contacts formed in the self-aligned openings are electrically connected to corresponding semiconductor posts.

Abstract: A method for manufacturing a semiconductor device that includes forming a pillar pattern including a sidewall contact over a semiconductor substrate; forming a silicon layer in a lower portion disposed between the pillar patterns; implanting ions into the silicon layer; diffusing the implanted impurity ions into the inside of the pillar pattern to form an ion-implanting region; removing the silicon layer; and burying a conductive material in the lower portion disposed between the pillar patterns. The method can prevent a floating body effect by adding a process of a vertical channel transistor.

Abstract: According to one embodiment, a semiconductor device includes a first semiconductor region, a second semiconductor region, a third semiconductor region, a fourth semiconductor region, a gate region, a gate insulating film, and an electric field relaxation region. The first semiconductor region includes a first portion and a second portion. The second semiconductor region includes a third portion and a fourth portion. The third semiconductor region includes a fifth portion and a sixth portion. The fourth semiconductor region is adjacent to the sixth portion. The gate region is provided inside a trench made in a second direction orthogonal to the first direction. The gate insulating film is provided between the gate region and an inner wall of the trench. The electric field relaxation region is provided between the third portion and the fifth portion and has an impurity concentration lower than an impurity concentration of the third semiconductor region.

Abstract: One aspect of the present subject matter relates to a memory. A memory embodiment includes a nanofin transistor having a first source/drain region, a second source/drain region above the first source/drain region, and a vertically-oriented channel region between the first and second source/drain regions. The nanofin transistor also has a surrounding gate insulator around the nanofin structure and a surrounding gate surrounding the channel region and separated from the nanofin channel by the surrounding gate insulator. The memory includes a data-bit line connected to the first source/drain region, at least one word line connected to the surrounding gate of the nanofin transistor, and a stacked capacitor above the nanofin transistor and connected between the second source/drain region and a reference potential. Other aspects are provided herein.

Abstract: Multiple threshold voltage (Vt) field-effect transistor (FET) devices and techniques for the fabrication thereof are provided. In one aspect, a FET device is provided including a source region; a drain region; at least one channel interconnecting the source and drain regions; and a gate, surrounding at least a portion of the channel, configured to have multiple threshold voltages due to the selective placement of at least one band edge metal throughout the gate.

Abstract: Vertical field effect transistor semiconductor structures and methods for fabrication of the vertical field effect transistor semiconductor structures provide an array of semiconductor pillars. Each vertical portion of each semiconductor pillar in the array of semiconductor pillars has a linewidth greater than a separation distance to an adjacent semiconductor pillar. Alternatively, the array may comprise semiconductor pillars with different linewidths, optionally within the context of the foregoing linewidth and separation distance limitations. A method for fabricating the array of semiconductor pillars uses a minimally photolithographically dimensioned pillar mask layer that is annularly augmented with at least one spacer layer prior to being used as an etch mask.

Abstract: A semiconductor device having a saddle fin gate and a method for manufacturing the same are presented. The semiconductor device includes a semiconductor substrate, an isolation structure, and gates. The semiconductor substrate is defined with first grooves in gate forming areas. The isolation structure is formed in the semiconductor substrate and is defined with second grooves which expose front and rear surfaces of the gate forming areas. The gates are formed within the first grooves in the gate forming areas. Gates are also formed in the second grooves of the isolation structure to cover the exposed front and rear surfaces of the gate forming areas. The second grooves are wider at the lower portions that at the upper portions.

Abstract: A semiconductor device having trench gates in element regions R1 formed in a semiconductor substrate. Second trenches T2 having the same depth as that of first trenches T1 making up the trench gates are provided along a marginal area of the semiconductor substrate.

Abstract: In a transistor region, a source interconnect layer and a gate electrode are buried in trenches. A source extending region is provided adjacent to the transistor region or in the transistor region, and a source interconnect layer is designed to protrude from the upper end of a trench. This source interconnect layer is connected to a source electrode formed in the transistor region immediately above the trench. A gate extending region is provided outside the source extending region, and the gate electrode and a gate interconnect layer are connected. The gate electrode is formed by performing etchback without forming a resist pattern, after a polysilicon film is formed. Here, the polysilicon film remains like a side-wall on the sidewall of the portion of the source interconnect layer protruding from the upper end of the trench.

Abstract: A semiconductor component comprises a semiconductor body comprising a first component electrode arranged on one of the surfaces of the semiconductor body, a second component electrode arranged on one of the surfaces of the semiconductor body, and a component control electrode arranged on one of the surfaces of the semiconductor body. In this case, active semiconductor element cells are arranged in a first active cell array of the semiconductor body, the semiconductor element cells comprising a first cell electrode, a second cell electrode and a cell control electrode and also a drift path between the cell electrodes. At least the component control electrode is arranged on a partial region of the semiconductor body and a second active cell array is additionally situated in the partial region of the semiconductor body below the component control electrode.

Abstract: There is provided a semiconductor device formed of a highly integrated high-speed CMOS inverter coupling circuit using SGTs provided on at least two stages. A semiconductor device according to the present invention is formed of a CMOS inverter coupling circuit in which n (n is two or above) CMOS inverters are coupled with each other, each of the n inverters has: a pMOS SGT; an nMOS SGT, an input terminal arranged so as to connect a gate of the pMOS SGT with a gate of the nMOS SGT; an output terminal arranged to connect a drain diffusion layer of the pMOS SGT with a drain diffusion layer of the nMOS SGT in an island-shaped semiconductor lower layer; a pMOS SGT power supply wiring line arranged on a source diffusion layer of the pMOS SGT; and an nMOS SGT power supply wiring line arranged on a source diffusion layer of the NMOS SGT, and an n?1th output terminal is connected with an nth input terminal.

Abstract: A MOS device includes first and second source/drains spaced apart relative to one another. A channel is formed in the device between the first and second source/drains. A gate is formed in the device between the first and second source/drains and proximate the channel, the gate being electrically isolated from the first and second source/drains and the channel. The gate is configured to control a conduction of the channel as a function of a potential applied to the gate. The MOS device further includes an energy filter formed between the first source/drain and the channel. The energy filter includes an impurity band operative to control an injection of carriers from the first source/drain into the channel.

Abstract: A method (that produces a structure) patterns at least two wires of semiconductor material such that a first wire of the wires has a larger perimeter than a second wire of the wires. The method performs an oxidation process simultaneously on the wires to form a first gate oxide on the first wire and a second gate oxide on the second wire. The first gate oxide is thicker than the second gate oxide. The method also forms gate conductors over the first gate oxide and the second gate oxide, forms sidewall spacers on the gate conductors, and dopes portions of the first wire and the second wire not covered by the sidewall spacers and the gate conductors to form source and drain regions within the first wire and the second wire.

Abstract: A substrate is provided. A pillar protruding out of a surface of the substrate is already formed on the substrate, and a patterned layer is already formed on the pillar. The pillar includes a lower part, a channel region, and an upper part from bottom to top, and the lower part has a first doped region. A gate dielectric layer is formed on a sidewall at one side of the pillar. A surrounding gate is formed on the gate dielectric layer located on the channel region, and a base line electrically connected to the channel region is formed on a sidewall at the other side of the pillar. A second doped region is formed in the upper part of the pillar.

Abstract: A planar transistor device includes two independent gates (a first and second gates) along with a semiconductor channel lying between the gates. The semiconductor channel is formed of a first material. The channel includes opposed ends comprising dielectric zone with a channel region positioned between the gates. The dielectric zones comprises an oxide of the first material.

Abstract: A method for forming a vertical channel transistor in a semiconductor memory device includes: forming a plurality of pillars over a substrate so that the plurality of pillars are arranged in a first direction and a second direction crossing the first direction, and so that each of the pillars has a hard mask pattern thereon; forming an insulation layer to fill a regions between the pillars; forming a mask pattern over a resultant structure including the insulation layer, wherein the mask pattern has openings exposing gaps between each two adjacent pillars in the first direction; etching the insulation layer to a predetermined depth using the mask pattern as an etching barrier to form trenches; and filling the trenches with a conductive material to form word lines extending in the first direction.

Abstract: Manufacturing a power transistor by forming a gate structure on a first layer, forming a trench in the first layer, self aligned with the gate structure, and forming part of the transistor in the trench. By forming a spacer next to the gate, the spacer and gate can be used as a mask when forming the trench, to allow space for a source region next to the gate. The self-aligning rather than forming the gate after the trench means the alignment is more accurate, allowing size reduction. Another aspect involves forming a trench in a first layer, filling the trench, forming a second layer on either side of the trench with lateral overgrowth over the trench, and forming a source region in the second layer to overlap the trench. This overlap can enable the chip area to be reduced.

Abstract: This invention discloses a semiconductor power device disposed on a semiconductor substrate includes a plurality of deep trenches with an epitaxial layer filling said deep trenches and a simultaneously grown top epitaxial layer covering areas above a top surface of said deep trenches over the semiconductor substrate. A plurality of trench MOSFET cells disposed in said top epitaxial layer with the top epitaxial layer functioning as the body region and the semiconductor substrate acting as the drain region whereby a super-junction effect is achieved through charge balance between the epitaxial layer in the deep trenches and regions in the semiconductor substrate laterally adjacent to the deep trenches. Each of the trench MOSFET cells further includes a trench gate and a gate-shielding dopant region disposed below and substantially aligned with each of the trench gates for each of the trench MOSFET cells for shielding the trench gate during a voltage breakdown.

Abstract: A method for manufacturing a semiconductor device includes determining an active region in a semiconductor substrate, forming a recess in a gate region crossing over the active region, annealing an oxide layer formed in the recess to oxidize the active region in the gate region, and etching the active region by using the oxidized active region as an etch mask.

Abstract: A method for fabricating a vertical channel type non-volatile memory device includes repeatedly forming stacks of conductive layers and inter-layer insulation layers over a substrate, and performing an etch process using an etch gas which etches both the conductive layers and the inter-layer insulation layers to form a contact hole exposing the substrate, wherein the etch gas maintains a selectivity between the inter-layer insulation layers and the conductive layers with a ratio of different etching rates ranging from approximately 0.1 to approximately 2.

Abstract: A trench MOSFET with high cell density is disclosed where there is a heavily doped contact region on the top surface of mesas between a pair of gate trenches. The present invention can prevent the degradation of avalanche capability when shrinking the device in prior art.

Abstract: A MOS transistor having an increased gate-drain capacitance is described. One embodiment provides a drift zone of a first conduction type. At least one transistor cell has a body zone, a source zone separated from the drift zone by the body zone, and a gate electrode, which is arranged adjacent to the body zone and which is dielectrically insulated from the body zone by a gate dielectric. At least one compensation zone of the first conduction type is arranged in the drift zone. At least one feedback electrode is arranged at a distance from the body zone, which is dielectrically insulated from the drift zone by a feedback dielectric and which is electrically conductively connected to the gate electrode.

Abstract: A method for fabricating a semiconductor device may include: forming an outer trench, including: a first trench, and a second trench formed under the first trench, the second trench being formed by etching a substrate, forming a dielectric layer, which fills the second trench, by performing a thermal oxidation process, such that a width of the second trench is less than a width of the first trench, forming a gate dielectric layer along a surface of a semiconductor structure including the dielectric layer, and forming a gate electrode, which fills a remaining portion of the outer trench, over the gate dielectric layer.

Abstract: A method for fabricating a semiconductor device includes etching a substrate to form a first trench pattern, forming spacers over sidewalls of the first trench pattern, etching a bottom portion of the first trench pattern using the spacers as a barrier to form a second trench pattern, performing an isotropic etching on the second trench pattern to round sidewalls of the second trench pattern and form a bulb pattern, and forming a gate over a recess pattern including the first trench pattern, the rounded second trench pattern and the bulb pattern.

Abstract: A fin-shaped structure is formed from a semiconductor material. The fin-shaped structure is processed to generate a tensile strain within the semiconductor material along a longitudinal direction of the fin.

Abstract: A method of fabricating a semiconductor device having a vertical channel transistor, the method including forming a hard mask pattern on a substrate, forming a preliminary active pillar by etching the substrate using the hard mask pattern as an etch mask, reducing a width of the preliminary active pillar to form an active pillar having a width less than that of the hard mask pattern, forming a lower source/drain region by implanting impurity ions into the substrate adjacent to the active pillar using the hard mask pattern as an ion implantation mask, and forming an upper source/drain region on the active pillar and vertically separated from the lower source/drain region.

Abstract: A method for forming a vertical channel transistor of a semiconductor device includes forming a plurality of pillar patterns over a substrate, forming a gate insulation layer encapsulating the resultant pillar pattern structure, forming a surrounding gate electrode conduction layer surrounding the sidewalls of the pillar pattern including the gate insulation layer, filling a sacrificial layer to a predetermined height of a surrounding gate electrode in a gap region between neighboring pillar patterns having the surrounding gate electrode conduction layer, and forming the surrounding gate electrode by removing a portion of the surrounding gate electrode conduction layer exposed by the sacrificial layer.

Abstract: A method for fabricating a semiconductor device includes forming a plurality of trenches, including applying a first mask, forming a first polysilicon region in at least some of the plurality of trenches, forming a inter-polysilicon dielectric region and a termination protection region, including applying a second mask, forming a second polysilicon region in the at least some of the plurality of trenches, forming a first electrical contact to the first polysilicon region and forming a second electrical contact to the second polysilicon region, including applying a third mask, disposing a metal layer, and forming a source metal region and a gate metal region, including applying a fourth mask.

Abstract: A method for fabricating a semiconductor apparatus including a buried gate removes factors deteriorating the operational reliability of the semiconductor device such as the electrical connection between a contact and a word line, and increases a processing margin when forming the contact disposed on a source/drain region. The method includes forming a recess in a semiconductor substrate, forming a gate in a lower portion of the recess, forming a first insulation layer over the gate, growing silicon over the first insulation layer in the recess, and depositing a second insulation layer over the semiconductor substrate and in the remaining portion of the recess.

Abstract: A method of making an electronic device comprises solution depositing a dielectric composition onto a substrate and polymerizing the dielectric composition to form a gate dielectric. The dielectric composition comprises a polymerizable resin and zirconium oxide nanoparticles.

Abstract: A first local wiring includes a convex portion protruding from a base and a protrusion protruding from a side surface of the convex portion. The convex portion of the first local wiring is connected to a lower conductive region of a first transistor while the protrusion is connected to a gate electrode of a second transistor. Moreover, the lower surface of the protrusion of the first local wiring is arranged at a height equal to or lower than the upper surface of the gate electrode of the second transistor.

Abstract: This invention discloses a new trenched vertical semiconductor power device that includes a capacitor formed between a conductive layer covering over an inter-dielectric layer disposed on top of a trenched gate. In a specific embodiment, the trenched vertical semiconductor power device may be a trenched metal oxide semiconductor field effect transistor (MOSFET) power device. The trenched gate is a trenched polysilicon gate and the conductive layer is a second polysilicon layer covering an inter-poly dielectric layer disposed on top of the trenched polysilicon gate. The conductive layer is further connected to a source of the vertical power device.

Abstract: A manufacturing method of a semiconductor device includes: forming multiple trenches on a semiconductor substrate; forming a second conductive type semiconductor film in each trench to provide a first column with the substrate between two trenches and a second column with the second conductive type semiconductor film in the trench, the first and second columns alternately repeated along with a predetermined direction; thinning a second side of the substrate; and increasing an impurity concentration in a thinned second side so that a first conductive type layer is provided. The impurity concentration of the first conductive type layer is higher than the first column. The first column provides a drift layer so that a vertical type first-conductive-type channel transistor is formed.

Abstract: A semiconductor device and methods for its fabrication are provided. The semiconductor device comprises a trench formed in the semiconductor substrate and bounded by a trench wall extending from the semiconductor surface to a trench bottom. A drain region and a source region, spaced apart along the length of the trench, are formed along the trench wall, each extending from the surface toward the bottom. A channel region is formed in the substrate along the trench wall between the drain region and the source region and extending along the length of the trench parallel to the substrate surface. A gate insulator and a gate electrode are formed overlying the channel.

Abstract: A semiconductor structure is provided that includes a first device region including a first threshold voltage adjusting layer located atop a semiconductor substrate, a gate dielectric located atop the first threshold voltage adjusting layer, and a gate conductor located atop the gate dielectric. The structure further includes a second device region including a gate dielectric located atop the semiconductor substrate, and a gate conductor located atop the gate dielectric; and a third device region including a gate dielectric located atop the semiconductor substrate, a second threshold voltage adjusting layer located atop the gate dielectric, and a gate conductor located atop the second threshold voltage adjusting layer.

Abstract: A method for forming a vertical channel transistor in a semiconductor device includes providing a substrate, forming pillar patterns extending perpendicular from the upper surface of the substrate, forming a spin on carbon (SOC) layer in a gap region between the pillar patterns, forming photoresist patterns above a resultant structure where the SOC layer is filled to expose a region for an isolation trench, etching the SOC layer between the photoresist pattern barriers to expose the region for the isolation trench, and etching the exposed structure to a certain depth forming the isolation trench.

Abstract: A manufacturing method is provided for a power semiconductor device that enables reducing its on-state voltage and power loss. The semiconductor device includes a set of L-shaped trench gates 3 each formed, from the top-side surface of a p base layer 2, perpendicularly with respect to a first main surface of an n? layer 1, to reach into a location of the n? layer 1. At the lower ends of each of the trench gates 3, bottom portions 3d are provided to unilaterally extend a predetermined length in one direction parallel to the first main surface of the n? layer 1. In addition, the extending end of one of the bottom portions 3d opposes that of the other bottom portion, on the extending side of the bottom portions 3d, and the interspace between each pair of adjacent bottom portions 3d is set narrower than any other interspace between the trench-gate parts that are perpendicularly formed with respect to the first main surface of the n? layer 1.

Abstract: The invention includes a method of forming a semiconductor construction. Dopant is implanted into the upper surface of a monocrystalline silicon substrate. The substrate is etched to form a plurality of trenches and cross-trenches which define a plurality of pillars. After the etching, dopant is implanted within the trenches to form a source/drain region that extends less than an entirety of the trench width. The invention includes a semiconductor construction having a bit line disposed within a semiconductor substrate below a first elevation. A wordline extends elevationally upward from the first elevation and substantially orthogonal relative to the bit line. A vertical transistor structure is associated with the wordline. The transistor structure has a channel region laterally surrounded by a gate layer and is horizontally offset relative to the bit line.

Abstract: Multiple threshold voltage (Vt) field-effect transistor (FET) devices and techniques for the fabrication thereof are provided. In one aspect, a FET device is provided including a source region; a drain region; at least one channel interconnecting the source and drain regions; and a gate, surrounding at least a portion of the channel, configured to have multiple threshold voltages due to the selective placement of at least one band edge metal throughout the gate.

Abstract: A semiconductor device having a saddle fin gate and a method for manufacturing the same are presented. The semiconductor device includes a semiconductor substrate, an isolation structure, and gates. The semiconductor substrate is defined with first grooves in gate forming areas. The isolation structure is formed in the semiconductor substrate and is defined with second grooves which expose front and rear surfaces of the gate forming areas. The gates are formed within the first grooves in the gate forming areas. Gates are also formed in the second grooves of the isolation structure to cover the exposed front and rear surfaces of the gate forming areas. The second grooves are wider at the lower portions that at the upper portions.

Abstract: A method of fabricating a vertical channel transistor for a semiconductor device includes forming, on a substrate, a plurality of active pillars each having a gate electrode formed on and surrounding a lower portion thereof; forming a first insulation layer over the active pillars to fill a gap region between the active pillars; partially removing the first insulation layer to exposes a circumferential surface of the gate electrode in all directions, without exposing the substrate in the gap region between the active pillars; forming a conductive layer on the remaining first insulation layer to fill the gap region between the active pillars; and patterning the conductive layer to form a word line that surrounds and contacts the circumferential surface of the gate electrode in all directions.

Abstract: Various structures and methods for improving the performance of trench-shielded power semiconductor devices and the like are described.

Abstract: A field effect transistor is provided. The field effect transistor includes a channel region, electrically conductive channel connection regions, and a control region. The electrically conductive channel connection regions adjoin the channel region along with a transistor dielectric. The control region is separated from the channel region by the transistor dielectric. In addition, the control region may comprise a monocrystalline material.

Abstract: There is provided a semiconductor device having a switching element, including a first semiconductor layer including a first, second and third surfaces, a first electrode connected to the first semiconductor layer, a plurality of second semiconductor layers selectively configured on the first surface, a third semiconductor layer configured on the second semiconductor layer, a second electrode configured to be contacted with the second semiconductor layer and the third semiconductor layer, a gate electrode formed over the first semiconductor layer, a first region including a first tale region, a density distribution of crystalline defects being gradually increased therein, a peak region crossing a current path applying to a forward direction in a p-n junction, a second tale region continued from the peak region, and a second region including a third tale region, the density distribution of the crystalline defects being gradually increased therein.

Abstract: The invention includes methods of forming field effect transistors, methods of forming field effect transistor gates, methods of forming integrated circuitry comprising a transistor gate array and circuitry peripheral to the gate array, and methods of forming integrated circuitry comprising a transistor gate array including first gates and second grounded isolation gates. In one implementation, a method of forming a field effect transistor includes forming masking material over semiconductive material of a substrate. A trench is formed through the masking material and into the semiconductive material. Gate dielectric material is formed within the trench in the semiconductive material. Gate material is deposited within the trench in the masking material and within the trench in the semiconductive material over the gate dielectric material. Source/drain regions are formed. Other aspects and implementations are contemplated.

Abstract: A semiconductor device includes a first semiconductor pillar, a first insulating film covering a side face of the first semiconductor pillar, a first electrode covering the first insulating film, a second semiconductor pillar, a second insulating film covering a side face of the second semiconductor pillar, and a second electrode covering the second insulating film. The top level of the second electrode is higher than the top level of the first electrode.

Abstract: A method of forming an integrated circuit includes forming a gate structure over a semiconductor body, and forming a shadowing structure over the semiconductor body laterally spaced from the gate structure, thereby defining an active area in the semiconductor body therebetween. The method further includes performing an angled implant into the gate structure, wherein the shadowing structure substantially blocks dopant from the angled implant from implanting into the active area, and performing a source/drain implant into the gate structure and the active area.

Abstract: A semiconductor device includes a pair of first source/drain regions disposed on a silicon substrate. A first silicon epitaxial layer pattern defines a gate forming region that exposes the silicon substrate between the pair of first source/drain regions. A first gate insulation layer is disposed on the silicon substrate in the gate forming region. A second gate insulation layer is disposed on a sidewall of the first silicon epitaxial layer pattern. A second silicon epitaxial layer pattern is disposed in the gate forming region and on the first silicon epitaxial layer pattern. A pair of second source/drain regions is disposed on the second silicon epitaxial layer pattern. A third gate insulation layer exposes the second silicon epitaxial layer pattern in the gate forming region and covers the pair of second source/drain regions. A gate is disposed on the second silicon epitaxial layer pattern in the gate forming region.