Abstract: The semiconductor memory device of the present invention includes a plurality of memory strings having a plurality of electrically reprogrammable memory cells connected in series, the memory strings having a column shaped semiconductor, a first insulation film formed around the column shaped semiconductor, a charge accumulation layer formed around the first insulation film, a second insulation film formed around the charge accumulation film and a plurality of electrodes formed around the second insulation film, a bit line connected to one end of the memory strings via a plurality of selection transistors, and a conducting layer extending in two dimensions and in which the plurality of electrodes of the memory strings and the plurality of electrodes of different memory strings are shared respectively, wherein each end part of the conducting layer is formed in step shapes in a direction parallel with the bit line.

Abstract: In a vertical-type semiconductor device, a method of manufacturing the same and a method of operating the same, the vertical-type semiconductor device includes a single-crystalline semiconductor pattern having a pillar shape provided on a substrate, a gate surrounding sidewalls of the single-crystalline semiconductor pattern and having an upper surface lower than an upper surface of the single-crystalline semiconductor pattern, a mask pattern formed on the upper surface of the gate, the mask pattern having an upper surface coplanar with the upper surface of the single-crystalline semiconductor pattern, a first impurity region in the substrate under the single-crystalline semiconductor pattern, and a second impurity region under the upper surface of the single-crystalline semiconductor pattern. The vertical-type pillar transistor formed in the single-crystalline semiconductor pattern may provide excellent electrical properties.

Abstract: A transistor device includes a drift layer having a first conductivity type, a body layer on the drift layer, the body layer having a second conductivity type opposite the first conductivity type, and a source region on the body layer, the source region having the first conductivity type. The device further includes a trench extending through the source region and the body layer and into the drift layer, a channel layer on the inner sidewall of the trench, the channel layer having the second conductivity type and having an inner sidewall opposite an inner sidewall of the trench, a gate insulator on the inner sidewall of the channel layer, and a gate contact on the gate insulator.

Abstract: A semiconductor device including a nonvolatile memory cell with a high performance and also a high reliability is provided. A nonvolatile memory cell includes a first n-well, a second n-well separated from the first n-well in a first direction, a selection transistor formed in the first n-well, a floating gate electrode formed to overlap with a part of the first n-well and a part of the second n-well in a plan view, and an n-conductivity-type semiconductor regions formed in the second n-well on both sides of the floating gate electrode. In write operation, ?7 V is applied to the drain of a selected nonvolatile memory cell, ?8 V is applied to the gate electrode of the selection transistor, and further ?3 V is applied to the n-conductivity-type semiconductor region for obtaining a higher write speed. Thereby, a selected nonvolatile memory cell is discriminated from an unselected nonvolatile memory cell.

Abstract: According to example embodiments, a semiconductor device includes a plurality of active pillars protruding from a substrate. Each active pillar includes a channel region between upper and lower doped regions. A contact gate electrode faces the channel region and is connected to a word line. The word line extends in a first direction. A bit line is connected to the lower doped region and extends in a second direction. The semiconductor device further includes a string body connection portion that connects the channel region of at least two adjacent active pillars of the plurality of active pillars.

Abstract: Disclosed is a semiconductor structure which includes a semiconductor substrate and a wiring layer on the semiconductor substrate. The wiring layer includes a plurality of fin-like structures comprising a first metal; a first layer of a second metal on each of the plurality of fin-like structures wherein the first metal is different from the second metal, the first layer of the second metal having a height less than each of the plurality of fin-like structures; and an interlayer dielectric (ILD) covering the plurality of fin-like structures and the first layer of the second metal except for exposed edges of the plurality of fin-like structures at predetermined locations, and at locations other than the predetermined locations, the height of the plurality of fin-like structures has been reduced so as to be covered by the ILD.

Abstract: A protection diode includes: a semiconductor substrate; a well region of a first conductivity type in the semiconductor substrate; a gate side diffusion region of a second conductivity type in the semiconductor substrate and joined to the well region; a grounding side diffusion region of the second conductivity type in the semiconductor substrate, separated from the gate side diffusion region, and joined to the well region; a gate side electrode connected between a gate of a transistor and the gate side diffusion region; and a grounding electrode connected to the grounding side diffusion region. Dopant impurity concentration in the grounding side diffusion region is lower than dopant impurity concentration in the gate side diffusion region.

Abstract: A field-effect semiconductor device is provided. The field-effect semiconductor device includes a semiconductor body with a first surface defining a vertical direction. In a vertical cross-section the field-effect semiconductor device further includes a vertical trench extending from the first surface into the semiconductor body. The vertical trench includes a field electrode, a cavity at least partly surrounded by the field electrode, and an insulation structure substantially surrounding at least the field electrode. Further, a method for producing a field-effect semiconductor device is provided.

Abstract: A semiconductor device includes: a substrate including a first epitaxial layer that has a first electrical type, and a second epitaxial layer; a transistor that includes a source region and an insulating spacer; an inner surrounding structure including an annular trench and an insulating spacer; an outer surrounding structure that has a second electrical type opposite to the first electrical type, and that is disposed adjacent to an upper surface of the second epitaxial layer to surround and contact the inner surrounding structure; and a conductive structure connecting to the source region, and the inner and outer surrounding structures.

Abstract: A semiconductor device includes a pillar-shaped silicon layer and a first-conductivity-type diffusion layer in an upper portion of the pillar-shaped silicon layer. A sidewall having a laminated structure including an insulating film and polysilicon resides on an upper sidewall of the pillar-shaped silicon layer. A top of the polysilicon of the sidewall is electrically connected to a top of the first-conductivity-type diffusion layer and has the same conductivity as the diffusion layer.

Abstract: A structure and method of forming a semiconductor device with a fin is provided. In an embodiment a hard mask is utilized to pattern a gate electrode layer and is then removed. After the hard mask has been removed, the gate electrode layer may be separated into individual gate electrodes.

Abstract: A semiconductor device includes a first pillar-shaped silicon layer formed on a planar silicon layer, a gate insulating film formed around the first pillar-shaped silicon layer, a first gate electrode formed around the gate insulating film, a gate line connected to the first gate electrode, a first first-conductivity-type diffusion layer formed in an upper portion of the first pillar-shaped silicon layer, a second first-conductivity-type diffusion layer formed in a lower portion of the first pillar-shaped silicon layer and an upper portion of the planar silicon layer, a first sidewall having a laminated structure of an insulating film and polysilicon and being formed on an upper sidewall of the first pillar-shaped silicon layer and an upper portion of the first gate electrode, and a first contact formed on the first first-conductivity-type diffusion layer and the first sidewall.

Abstract: Semiconductor devices having vertical channel transistors are provided. The semiconductor device includes an insulation layer on a substrate and a buried bit line on the insulation layer. The buried bit line extends in a first direction. An active pillar is disposed on the buried bit line. The active pillar includes a lower dopant region, a channel region having a first sidewall and an upper dopant region vertically stacked on the buried bit line. A contact gate electrode is disposed to be adjacent to the first sidewall of the channel region. A word line is electrically connected to the contact gate electrode. The word line extends in a second direction intersecting the first direction. A string body connector is electrically connected to the channel region. Related methods are also provided.

Abstract: A semiconductor memory device may include a common source region on a substrate, an active pattern between the substrate and the common source region, a gate pattern facing a sidewall of the active pattern, a gate dielectric pattern between the gate pattern and the active pattern, a variable resistance pattern between the common source region and the active pattern, and an interconnection line.

Abstract: A semiconductor memory device is disclosed. In one particular exemplary embodiment, the semiconductor memory device includes a plurality of memory cells arranged in an array of rows and columns. Each memory cell may include a first region connected to a source line extending in a first orientation. Each memory cell may also include a second region connected to a bit line extending a second orientation. Each memory cell may further include a body region spaced apart from and capacitively coupled to a word line, wherein the body region is electrically floating and disposed between the first region and the second region. The semiconductor device may also include a first barrier wall extending in the first orientation and a second barrier wall extending in the second orientation and intersecting with the first barrier wall to form a trench region configured to accommodate each of the plurality of memory cells.

Abstract: A device includes a wafer substrate, a conical frustum structure formed in the wafer substrate, and a gate all-around (GAA) structure circumscribing the middle portion of the conical frustum structure. The conical frustum structure includes a drain formed at a bottom portion of the conical frustum, a source formed at a top portion of the vertical conical frustum, and a channel formed at a middle portion of the conical frustum connecting the source and the drain. The GAA structure overlaps with the source at one side of the GAA structure, crosses over the channel, and overlaps with the drain at another side of the GAA structure.

Abstract: A semiconductor device including a connecting structure includes an edge region, a first trench and a second trench running toward the edge region, a first electrode within the first trench, and a second electrode within the second trench, the first and second electrodes being arranged in a same electrode plane with regard to a main surface of a substrate of the electronic device within the trenches, and the first electrode extending, at an edge region side end of the first trench, farther toward the edge region than the second electrode extends, at an edge region side end of the second trench, toward the edge region.

Abstract: A power device integrated on a semiconductor substrate and having a plurality of conductive bridges within a trench gate structure. In an embodiment, a semiconductor substrate includes a trench having sidewalls and a bottom, the walls and bottom are covered with a first insulating coating layer which then also includes a conductive gate structure. An embodiment provides the formation of the conductive gate structure with covering at least the sidewalls with a second conductive coating layer of a first conductive material. This results in a conductive central region of a second conductive material having a different resistivity than the first conductive material forming a plurality of conductive bridges between said second conductive coating layer and said conductive central region.

Abstract: The semiconductor memory device of the present invention includes a plurality of memory strings having a plurality of electrically reprogrammable memory cells connected in series, the memory strings having a column shaped semiconductor, a first insulation film formed around the column shaped semiconductor, a charge accumulation layer formed around the first insulation film, a second insulation film formed around the charge accumulation film and a plurality of electrodes formed around the second insulation film, a bit line connected to one end of the memory strings via a plurality of selection transistors, and a conducting layer extending in two dimensions and in which the plurality of electrodes of the memory strings and the plurality of electrodes of different memory strings are shared respectively, wherein each end part of the conducting layer is formed in step shapes in a direction parallel with the bit line.

Abstract: An electronic device can include a first layer having a primary surface, a well region lying adjacent to the primary surface, and a buried doped region spaced apart from the primary surface and the well region. The electronic device can also include a trench extending towards the buried doped region, wherein the trench has a sidewall, and a sidewall doped region along the sidewall of the trench, wherein the sidewall doped region extends to a depth deeper than the well region. The first layer and the buried region have a first conductivity type, and the well region has a second conductivity type opposite that of the first conductivity type. The electronic device can include a conductive structure within the trench, wherein the conductive structure is electrically connected to the buried doped region and is electrically insulated from the sidewall doped region. Processes for forming the electronic device are also described.

Abstract: The semiconductor device includes: a columnar silicon layer on the planar silicon layer; a first n+ type silicon layer formed in a bottom area of the columnar silicon layer; a second n+ type silicon layer formed in an upper region of the columnar silicon layer; a gate insulating film formed in a perimeter of a channel region between the first and second n+ type silicon layers; a gate electrode formed in a perimeter of the gate insulating film, and having a first metal-silicon compound layer; an insulating film formed between the gate electrode and the planar silicon layer, an insulating film sidewall formed in an upper sidewall of the columnar silicon layer; a second metal-silicon compound layer formed in the planar silicon layer; and an electric contact formed on the second n+ type silicon layer.

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: A super-junction trench MOSFET is disclosed for high voltage device by applying a first doped column region of first conductivity type between a pair of second doped column regions of second conductivity type adjacent to sidewalls of a pair of deep trenches with buried voids in each unit cell for super-junction. Meanwhile, at least one trenched gate and multiple trenched source-body contacts are formed in each unit cell between the pair of deep trenches.

Abstract: A super-junction trench MOSEET is disclosed for high voltage device by applying a first doped column region of first conductivity type between a pair of second doped column regions of second conductivity type adjacent to sidewalls of a pair of deep trenches in each unit cell for super-junction. Meanwhile, at least one trenched gate and multiple trenched source-body contacts are formed in each unit cell between the pair of deep trenches.

Abstract: A three-dimensional nonvolatile memory device and a method for fabricating the same include a semiconductor substrate, a plurality of active pillars, a plurality of gate electrodes, and a plurality of supporters. The semiconductor substrate includes a memory cell region and a contact region. The active pillars extend in the memory cell region perpendicularly to the semiconductor substrate. The gate electrodes intersect the active pillars, extend from the memory cell region to the contact region and are stacked on the semiconductor substrate. The supporters extend in the contact region perpendicularly to the semiconductor substrate to penetrate at least one or more of the gate electrodes.

Abstract: A vertical transistor component is produced by providing a semiconductor body with a first surface and a second surface, producing at least one gate contact electrode in a trench, the trench extending from the first surface through the semiconductor body to the second surface, and producing at least one gate electrode connected to the at least one gate contact electrode in the region of the first surface.

Abstract: A semiconductor device includes a semiconductor substrate having first and second regions, a first pillar transistor, and a second pillar transistor, wherein the first pillar transistor comprises a first semiconductor pillar disposed in the first region, and a first gate electrode covering a side surface of the first semiconductor pillar, wherein the second pillar transistor comprises a second semiconductor pillar disposed in the second region, and a second gate electrode covering a side surface of the second semiconductor pillar, wherein the first gate electrode is different in height from the second gate electrode, and the first and second pillar transistors form a CMOS device.

Abstract: The semiconductor device includes: a columnar silicon layer on the planar silicon layer; a first n+ type silicon layer formed in a bottom area of the columnar silicon layer; a second n+ type silicon layer formed in an upper region of the columnar silicon layer; a gate insulating film formed in a perimeter of a channel region between the first and second n+ type silicon layers; a gate electrode formed in a perimeter of the gate insulating film, and having a first metal-silicon compound layer; an insulating film formed between the gate electrode and the planar silicon layer, an insulating film sidewall formed in an upper sidewall of the columnar silicon layer; a second metal-silicon compound layer formed in the planar silicon layer; and an electric contact formed on the second n+ type silicon layer.

Abstract: A method of manufacturing a semiconductor device, the method including providing a substrate, the substrate including single crystalline silicon and having the first region and a second region; growing a pillar from a top surface of the substrate in the first region; forming a vertical channel transistor including a first gate structure such that first gate structure surrounds a central portion of the pillar; and forming a second transistor on the second region of the substrate such that the second transistor includes a second gate structure.

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: In a vertical-type semiconductor device, a method of manufacturing the same and a method of operating the same, the vertical-type semiconductor device includes a single-crystalline semiconductor pattern having a pillar shape provided on a substrate, a gate surrounding sidewalls of the single-crystalline semiconductor pattern and having an upper surface lower than an upper surface of the single-crystalline semiconductor pattern, a mask pattern formed on the upper surface of the gate, the mask pattern having an upper surface coplanar with the upper surface of the single-crystalline semiconductor pattern, a first impurity region in the substrate under the single-crystalline semiconductor pattern, and a second impurity region under the upper surface of the single-crystalline semiconductor pattern. The vertical-type pillar transistor formed in the single-crystalline semiconductor pattern may provide excellent electrical properties.

Abstract: The present application discloses a method for manufacturing a gate-all-around field effect transistor, comprising the steps of: forming a suspended fin in a semiconductor substrate; forming a gate stack around the fin; and forming source/drain regions in the fin on both sides of the gate stack, wherein an isolation dielectric layer is formed in a portion of the semiconductor substrate which is adjacent to bottom of both the fin and the gate stack. The present invention relates to a method for manufacturing a gate-all-around device on a bulk silicon substrate, which suppress a self-heating effect and a floating-body effect of the SOI substrate, and lower a manufacture cost. The inventive method is a conventional top-down process with respect to a reference plane, which can be implemented as a simple manufacture process, and is easy to be integrated into and compatible with a planar CMOS process. The inventive method suppresses a short channel effect and promotes miniaturization of MOSFETs.

Abstract: Methods of fabricating charge storage transistors are described, along with apparatus and systems that include them. In one such method, a pillar of epitaxial silicon is formed. At least first and second charge storage nodes (e.g., floating gates) are formed around the pillar of epitaxial silicon at different levels. A control gate is formed around each of the charge storage nodes. Additional embodiments are also described.

Abstract: Memory devices are described along with methods for manufacturing. A memory device as described herein comprises a plurality of word lines overlying a plurality of bit lines, and a plurality of field effect transistors. Field effect transistors in the plurality of field effect transistors comprises a first terminal electrically coupled to a corresponding bit line in the plurality of bit lines, a second terminal overlying the first terminal, and a channel region separating the first and second terminals and adjacent a corresponding word line in the plurality of word lines. The corresponding word line acts as the gate of the field effect transistor. A dielectric separates the corresponding word line from the channel region. A memory plane comprises programmable resistance memory material electrically coupled to respective second terminals of the field effect transistors, and conductive material on the programmable resistance memory material and coupled to a common voltage.

Abstract: A method for forming power semiconductor devices having an inter-electrode dielectric (IPD) layer inside a trench includes providing a semiconductor substrate with a trench, lining the sidewalls and bottom of the trench with a first layer of dielectric material, filling the trench with a first layer of conductive material to form a first electrode, recessing the first layer of dielectric material and the first layer of conductive material to a first depth inside the trench, forming a layer of polysilicon material on a top surface of the dielectric material and conductive material inside the trench, oxidizing the layer of polysilicon material, and forming a second electrode inside the trench atop the oxidized layer and isolated from trench sidewalls by a second dielectric layer. The oxidation step can be enhanced by either chemically or physically altering the top portion polysilicon such as by implanting impurities.

Abstract: Provided is a semiconductor memory device. In the semiconductor memory device, a lower selection gate controls a first channel region that is defined at a semiconductor substrate and a second channel region that is defined at the lower portion of an active pattern disposed on the semiconductor substrate. The first threshold voltage of the first channel region is different from the second threshold voltage of the second channel region.

Abstract: A semiconductor device includes a semiconductor substrate, a first diffusion region, a gate insulating film, a gate electrode, a second diffusion region and a contact plug. The semiconductor substrate includes a base and at least a pillar. The first diffusion region is disposed in the base. The gate insulating film covers a side surface of the pillar. The gate electrode is separated from the pillar by the gate insulating film. The second diffusion region is disposed in an upper portion of the pillar. The contact plug is connected to the second diffusion region. The contact plug is connected to the entirety of the top surface of the pillar.

Abstract: In a vertical-type memory device and a method of manufacturing the vertical-type memory device, the vertical memory device includes an insulation layer pattern of a linear shape provided on a substrate, pillar-shaped single-crystalline semiconductor patterns provided on both sidewalls of the insulation layer pattern and transistors provided on a sidewall of each of the single-crystalline semiconductor patterns. The transistors are arranged in a vertical direction of the single-crystalline semiconductor pattern, and thus the memory device may be highly integrated.

Abstract: The trench type semiconductor device includes a gate insulating film placed on the bottom surface and the sidewall surface of the trench formed from the surface of a first base layer; a gate electrode placed on the gate insulating film and fills up into a trench; an interlayer insulating film covering the gate electrode; a second base layer placed on the surface of the first base layer, and is formed more shallowly than the bottom surface of the trench; a source layer placed on the surface of the second base layer; a source electrode connected to the second base layer in the bottom surface of a self-aligned contact trench formed in the second base layer by applying the interlayer insulating film as a mask, and is connected to the source layer in the sidewall surface; a drain layer placed at the back side of the first base layer; and a drain electrode placed at the drain layer, for achieving the minute structure by the self-alignment, reducing the on resistance, and improving the breakdown capability, and prov

Abstract: A gated-diode semiconductor device or similar component and a method of fabricating the device. The device features a gate structure disposed on a substrate over a channel and adjacent a source and a drain. The top of the source or drain region, or both, are formed so as to be at a higher elevation, in whole or in part, than the bottom of the gate structure. This configuration may be achieved by overlaying the gate structure and substrate with a profile layer that guides a subsequent etch process to create a sloped profile. The source and drain, if both are present, may be symmetrical or asymmetrical. This configuration significantly reduces dopant encroachment and, as a consequence, reduces junction leakage.

Abstract: A nonvolatile semiconductor memory device includes a semiconductor substrate that includes a trench, a charge storage layer that is formed inside of the trench, a first gate that is formed above a side surface and a bottom surface of the trench, a second gate that is formed beside the first gate, and that is formed above the charge storage layer, a first diffusion region that is formed on the semiconductor substrate inside of the trench, and a second diffusion region that is formed on the semiconductor substrate outside of the trench.

Abstract: Methods of manufacturing a semiconductor device including a semiconductor substrate and a hetero semiconductor region including a semiconductor material having a band gap different from that of the semiconductor substrate and contacting a portion of a first surface of the semiconductor substrate are taught herein, as are the resulting devices. The method comprises depositing a first insulating film on exposed portions of the first surface of the semiconductor substrate and on exposed surfaces of the hetero semiconductor material and forming a second insulating film between the first insulating film and facing surfaces of the semiconductor substrate and the hetero semiconductor region by performing a thermal treatment in an oxidizing atmosphere.

Abstract: An access device and a semiconductor device are disclosed. The access device includes a vertically oriented channel separating a lower source/drain region and an upper source/drain region, a gate dielectric disposed on the channel, and a unified gate electrode/connection line coupled to the channel across the gate dielectric, wherein the unified gate electrode/connection line comprises a descending lip portion disposed proximate to the gate dielectric and overlaying at least a portion of the lower source/drain region.

Abstract: A connecting structure for an electronic device includes an edge region of the device, a first trench and a second trench running toward the edge region, a first electrode within the first trench, and a second electrode within the second trench, the first and second electrodes being arranged in a same electrode plane with regard to a main surface of a substrate of the electronic device within the trenches, and the first electrode extending, at an edge region side end of the first trench, farther toward the edge region than the second electrode extends, at an edge region side end of the second trench, toward the edge region.

Abstract: A non-volatile memory device includes a semiconductor substrate having a first section including a substantially planar first top surface, a second section including a substantially planar second top surface, and a sidewall extending between the first and second top surfaces. The second top surface of the substrate is closer to a bottom surface of the substrate than is the first top surface. A charge storage pattern extends on the first and second top surfaces of the substrate and along the sidewall therebetween. A source region in the first section of the substrate extends from the first top surface into the second section of the substrate and has a stepped portion defined by the sidewall and the second top surface. Related fabrication methods and methods of operation are also discussed.

Abstract: A semiconductor memory device in which a vertical trench semiconductor-oxide-nitride-oxide-semiconductor (SONOS) memory cell is created in a semiconductor-on-insulator (SOI) substrate is provided that allows for the integration of dense non-volatile random access memory (NVRAM) cells in SOI-based complementary metal oxide semiconductor (CMOS) technology. The trench is processed using conventional trench processing and it is processed near the beginning of the inventive method that allows for the fabrication of the memory cell to be fully separated from SOI logic processing.

Abstract: In a semiconductor device and associated methods, the semiconductor device includes a substrate, an insulation layer on the substrate, a conductive structure on the insulation layer, the conductive structure including at least one metal silicide film pattern, a semiconductor pattern on the conductive structure, the semiconductor pattern protruding upwardly from the conductive structure, a gate electrode at least partially enclosing the semiconductor pattern, the gate electrode being spaced apart from the conductive structure, a first impurity region at a lower portion of the semiconductor pattern, and a second impurity region at an upper portion of the semiconductor pattern.

Abstract: A vertical transistor of a semiconductor device and a method for forming the same are disclosed. The vertical transistor comprises a silicon fin disposed on a semiconductor substrate, a source region disposed in the semiconductor substrate below a lower portion of the silicon fin, a drain region disposed in an upper portion of the silicon fin, a channel region disposed in a sidewall of the silicon fin between the source region and the drain region, a gate oxide film disposed in a surface of the semiconductor substrate and the sidewall of the silicon fin, and a pair of gate electrodes disposed on the gate oxide films.

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