Abstract: Provided is a method of manufacturing a semiconductor device. According to the method, a first buried oxide layer is formed in the semiconductor substrate in a first region, such that a first semiconductor layer is defined on the first buried oxide layer. An active portion is defined by forming a trench in the semiconductor substrate in a second region. A capping semiconductor pattern is formed on a top surface and an upper portion of a sidewall of the active portion. An oxide layer is formed by oxidizing the capping semiconductor pattern and an exposed lower portion of the sidewall of the active portion, such that the oxide layer surrounds a non-oxidized portion of the active portion. The non-oxidized portion of the active portion is a core and one end of the core is connected to a first optical device formed at the first semiconductor.

Abstract: Provided is a trench filling method, which includes: forming a silicon oxide liner on a semiconductor substrate with trenches formed therein, the trenches including narrow-width portions having a first minimum isolation width and wide-width portions having a second minimum isolation width being wider than the first minimum isolation width; forming an oxidation-barrier film on the silicon oxide liner; forming a silicon liner on the oxidation-barrier film; filling the narrow-width portions with a first filling material; filling the wide-width portions with a second filling material; and oxidizing the silicon liner.

Abstract: A method, in which a first isolating trench, filled with a dielectric material, and a second conducting trench, filled with an electrically conductive material, can be produced. To this end, the first and second trenches are etched with different trench widths, so that the first trench is filled completely with the dielectric material after a deposition of a dielectric layer over the entire surface with the edges covered, whereas the wider second trench is covered by the dielectric layer only on the inside walls. By anisotropic back-etching of the dielectric layer, the semiconductor substrate is exposed at the bottom of the second trench. Subsequently, the second trench is filled with an electrically conductive material and then represents a low-ohmic connection from the substrate surface to the buried structure located below the second trench.

Abstract: A method for fabricating a semiconductor device includes: providing a substrate; forming a plurality of trenches by etching the substrate; forming a first isolation layer by filling the plurality of the trenches with a first insulation layer; recessing the first insulation layer filling a first group of the plurality of the trenches to a predetermined depth; forming a liner layer over the first group of the trenches with the first insulation layer recessed to the predetermined depth; and forming a second isolation layer by filling the first group of the trenches, where the liner layer is formed, with a second insulation layer.

Abstract: A method of forming trench isolation with different depths of a semiconductor device is disclosed. A semiconductor substrate having a first mask layer formed thereon is first provided. A first etching process is performed with the first mask layer as an etching mask to form a shallow trench structure, followed by forming a first dielectric layer on the semiconductor substrate to fill the shallow trench structure. The first dielectric layer is then patterned to form a second mask layer which is used in a second etching process to form a deep trench structure. After that, a dielectric material is applied to fill the deep trench structure.

Abstract: First and second isolation trenches are formed into semiconductive material of a semiconductor substrate. The first isolation trench has a narrowest outermost cross sectional dimension which is less than that of the second isolation trench. An insulative layer is deposited to within the first and second isolation trenches effective to fill remaining volume of the first isolation trench within the semiconductive material but not that of the second isolation trench within the semiconductive material. The insulative layer comprises silicon dioxide deposited from flowing TEOS to the first and second isolation trenches. A spin-on-dielectric is deposited over the silicon dioxide deposited from flowing the TEOS within the second isolation trench within the semiconductive material, but not within the first isolation trench within the semiconductive material. The spin-on-dielectric is deposited effective to fill remaining volume of the second isolation trench within the semiconductive material.

Abstract: A method of forming a series of spaced trenches into a substrate includes forming a plurality of spaced lines over a substrate. Anisotropically etched sidewall spacers are formed on opposing sides of the spaced lines. Individual of the lines have greater maximum width than minimum width of space between immediately adjacent of the spacers between immediately adjacent of the lines. The spaced lines are removed to form a series of alternating first and second mask openings between the spacers. The first mask openings are located where the spaced lines were located and are wider than the second mask openings. Alternating first and second trenches are simultaneously etched into the substrate through the alternating first and second mask openings, respectively, to form the first trenches to be wider and deeper within the substrate than are the second trenches. Other implementations and embodiments are disclosed.

Abstract: A shallow isolation trench structure and methods of forming the same wherein the method of formation comprises a layered structure of a buffer film layer over a dielectric layer that is atop a semiconductor substrate. The buffer film layer comprises a material that is oxidation resistant and can be etched selectively to oxide films. The layered structure is patterned with a resist material and etched to form a shallow trench. A thin oxide layer is formed in the trench and the buffer film layer is selectively etched to move the buffer film layer back from the corners of the trench. An isolation material is then used to fill the shallow trench and the buffer film layer is stripped to form an isolation structure. When the structure is etched by subsequent processing step(s), a capped shallow trench isolation structure that covers the shallow trench corners is created.

Abstract: A method for manufacturing semiconductor device has forming a plurality of trenches having at least two kinds of aspect ratios on a semiconductor substrate, filling the plurality of trenches with a coating material containing silicon, forming a mask on the coating material in a part of the trenches among the plurality of trenches filled with the coating material, implanting an ion for accelerating oxidation of the coating material into the coating material in the trenches on which the mask is not formed, forming a first insulating film by oxidizing the coating materials into which the ion is implanted, removing the coating material from the part of the trenches after removing the mask and forming a second insulating film in the part of the trenches from which the coating material is removed.

Abstract: A nonvolatile memory device includes a floating gate formed over a semiconductor substrate, an insulator formed on a first sidewall of the floating gate, a dielectric layer formed on a second sidewall and an upper surface of the floating gate, and a control gate formed over the dielectric layer.

Abstract: Provided is a method of forming an isolation structure of a semiconductor device capable of minimizing the number of performing a patterning process and having trenches of various depths. The method includes partially etching the semiconductor substrate using a first patterning process to form first trenches and second trenches having a first depth. The semiconductor substrate has first to third regions. The first trenches are formed in the first region, and the second trenched are formed in the second region. The semiconductor substrate is partially etched using a second patterning process, so that third trenches are formed in the third region, and fourth trenches are formed in the second region. The fourth trenches extend from bottoms of the second trenches. The third trenches have a second depth, and the fourth trenches have a third depth. An isolation layer filling the first to fourth trenches is formed.

Abstract: A DRAM structure with buried word lines is described, including a semiconductor substrate, cell word lines buried in the substrate and separated from the same by a first gate dielectric layer, and isolation word lines buried in the substrate and separated from the same by a second gate dielectric layer. The top surfaces of the cell word lines and those of the isolation word lines are lower than the top surface of the substrate. The bottom surfaces of the isolation word lines are lower than those of the cell word lines.

Abstract: A liner removal process is described, wherein an excess portion of a conformal liner formed in a trench is substantially removed while reducing or minimizing damage to a bulk fill material in the trench.

Abstract: A planarization process may planarize a media disk that has data trenches between data features and larger servo trenches between servo features. A filler material layer is deposited on the media disk and provides step coverage of the trenches. The filler material has data recesses over the data trenches and servo recesses over the servo trenches that must be removed to produce a planar media surface. A first planarization process is used to remove the data recesses and a second planarization process is used to remove the servo recesses.

Abstract: Disclosed is a method for manufacturing a semiconductor device, which provides an isolation region in which a dense silicon oxide film is formed in a trench that requires high aspect ratio. The method includes forming an isolation trench using, as an etching mask, a nitride mask film formed on a substrate, forming a liner nitride film in the isolation trench, depositing a flowable silazane compound by a CVD method such that the height of the flowable silazane compound is higher than the upper surface of the nitride mask film from the upper portion of the trench, performing heat treatment under an oxidizing atmosphere to convert the flowable silazane compound film into a silicon oxide film and simultaneously densifying therefor, and planarizing the silicon oxide film to the height of the upper surface of the nitride mask film.

Abstract: A semiconductor structure and method of manufacturing the semiconductor structure, and more particularly to a semiconductor structure having reduced metal line resistance and a method of manufacturing the same in back end of line (BEOL) processes. The method includes forming a first trench extending to a lower metal layer Mx+1 and forming a second trench remote from the first trench. The method further includes filling the first trench and the second trench with conductive material. The conductive material in the second trench forms a vertical wiring line extending orthogonally and in electrical contact with an upper wiring layer and electrically isolated from lower metal layers including the lower metal layer Mx+1. The vertical wiring line decreases a resistance of a structure.

Abstract: An SOI structure including a semiconductor on insulator (SOI) substrate including a top silicon layer, an intermediate buried oxide (BOX) layer and a bottom substrate; at least two wells in the bottom substrate; a deep trench isolation (DTI) separating the two wells, the DTI having a top portion extending through the BOX layer and top silicon layer and a bottom portion within the bottom substrate wherein the bottom portion has a width that is larger than a width of the top portion; and at least two semiconductor devices in the silicon layer located over one of the wells, the at least two semiconductor devices being separated by a shallow trench isolation within the top silicon layer.

Abstract: A method of forming large microchannels in an integrated circuit by etching an enclosed trench into the substrate and later thinning the backside to expose the bottom of the trenches and to remove the material enclosed by the trench to form the large microchannels. A method of simultaneously forming large and small microchannels. A method of forming structures on the backside of the substrate around a microchannel to mate with another device.

Abstract: A method for forming a lateral passive device including a dual annular electrode is disclosed. The annular electrodes formed from the method include an anode and a cathode. The annular electrodes allow anode and cathode series resistances to be optimized to the lowest values at a fixed device area. In addition, the parasitic capacitance to a bottom plate (substrate) is greatly reduced.

Abstract: A description is given of a method for producing isolation trenches (32, 34) with different sidewall dopings on a silicon-based substrate wafer for use in the trench-isolated smart power technology. In this case, a first trench (32) having a first width and a second trench (34) having a second width which is greater than the first width are formed using a hard mask (30). The sidewalls of the first and second trenches are doped in accordance with a first doping type in order to produce sidewalls having a first doping. A material layer (50, 51, 60, 61) is deposited with a thickness determined so as to fill the first trench (32) completely up to and beyond the hard mask and to maintain the gap (34a) in the second trench (34). By means of isotropic etching the material layer is removed from the second trench, but residual material of the material layer is maintained in the first trench.

Abstract: A method of forming a non-planar transistor is provided. A substrate is provided. The substrate has a plurality of isolation regions to be formed and a plurality of fin regions to be formed. A first etching process is performed to form a plurality of first trenches having a first depth in the substrate within the isolation regions. At least a doping region is formed in the substrate within the fin regions. A second etching process is performed to deepen the first depth to a second depth and a plurality of fin structures are formed in the substrate within the fin regions. Lastly, a gate is formed on the fin structures.

Abstract: A semiconductor device includes a semiconductor substrate having a cell region and a peripheral region. A cell array is defined within the cell region, the cell array having first, second, third, and fourth sides. A first decoder is defined within the peripheral region and provided adjacent to the first side of the cell array. A first isolation structure is formed at a first boundary region provided between the first side of the cell array and the peripheral region. A first active region is formed at a second boundary region that is provided between the second side of the cell array and the peripheral region. The first isolation structure has a first portion that has a first depth and a second portion that has a second depth.

Abstract: Disclosed herein are flash memory devices and methods of making the same. According to one embodiment, a flash memory device includes first trenches formed in a semiconductor substrate and arranged in parallel, second trenches discontinuously formed in the semiconductor substrate and arranged between the first trenches, first isolation structures respectively formed within the first trenches, second isolation structures respectively formed within the second trenches, and active regions defined by the first isolation structures and the second isolation structures.

Abstract: A method for forming a trench structure is provided for a semiconductor and/or memory device, such as an DRAM device. In one embodiment, the method for forming a trench structure includes forming a trench in a semiconductor substrate, and exposing the sidewalls of the trench to an arsenic-containing gas to adsorb an arsenic containing layer on the sidewalls of the trench. A material layer is then deposited on the sidewalls of the trench to encapsulate the arsenic-containing layer between the material layer and sidewalls of the trench.

Abstract: Embodiments of the invention provide a method of creating vias and trenches with different length. The method includes depositing a plurality of dielectric layers on top of a semiconductor structure with the plurality of dielectric layers being separated by at least one etch-stop layer; creating multiple openings from a top surface of the plurality of dielectric layers down into the plurality of dielectric layers by a non-selective etching process, wherein at least one of the multiple openings has a depth below the etch-step layer; and continuing etching the multiple openings by a selective etching process until one or more openings of the multiple openings that are above the etch-stop layer reach and expose the etch-stop layer. Semiconductor structures made thereby are also provided.

Abstract: A MOS transistor suppressing a short channel effect includes a substrate, a first diffusion region and a second diffusion region separated from each other by a channel region in an upper portion of the substrate, a gate insulating layer including a first gate insulating layer disposed on a surface of the substrate in the channel region and a second gate insulating layer having a specified depth from the surface of the substrate to be disposed between the first diffusion region and the channel region, and a gate electrode disposed on the first gate insulating layer.

Abstract: According to the present disclosure, a flash memory device includes a semiconductor substrate that includes selection transistor regions and a memory cell region defined between the selection transistor region, first isolation layers formed in the selection transistor regions, and second isolation layers formed in the memory cell region. The second isolation layers have a lower height than the first isolation layers.

Abstract: Methods of forming a semiconductor trench and forming dual trenches and a structure for isolating devices are provided. The structure for isolating devices is disposed in a substrate having a periphery area and an array area. The structure for isolating devices includes a first isolation structure and a second isolation structure. The first isolation structure has a profile with at least three steps and is disposed in the substrate in the periphery area. The second isolation structure has a profile with at least two steps and is disposed in the substrate in the array area.

Abstract: In a method of forming an asymmetric recess, an asymmetric recessed gate structure filling the asymmetric recess, a method of forming the asymmetric recessed gate structure, a semiconductor device having the asymmetric recessed gate structure and a method of manufacturing the semiconductor device, a semiconductor substrate is etched to form a first sub-recess having a first central axis. A second sub-recess is formed under the first sub-recess. The second sub-recess is in communication with the first sub-recess. The second sub-recess has a second central axis substantially parallel with the first central axis. The second central axis is spaced apart from the first central axis.

Abstract: A semiconductor device having high aspect ratio isolation trenches and a method for manufacturing the same is presented. The semiconductor device includes a semiconductor substrate, a first insulation layer, and a second insulation layer. The semiconductor substrate has a second trench that is wider than a first trench. The first insulation layer is partially formed within the wider second trench in which the first insulation layer when formed clogs the opening of the narrower first trench. A cleaning of the first insulation layer unclogs the opening of the narrower first trench in which a second insulation layer can then be formed within both the first and second trenches.

Abstract: A method for fabricating a semiconductor device includes: providing a substrate; forming a plurality of trenches by etching the substrate; forming a first isolation layer by filling the plurality of the trenches with a first insulation layer; recessing the first insulation layer filling a first group of the plurality of the trenches to a predetermined depth; forming a liner layer over the first group of the trenches with the first insulation layer recessed to the predetermined depth; and forming a second isolation layer by filling the first group of the trenches, where the liner layer is formed, with a second insulation layer.

Abstract: A method for fabricating a semiconductor device, including (a) etching a semiconductor substrate to form a first trench defining an active region; (b) forming a first spacer on sidewalls of the first trench; (c) etching a bottom of the first trench to form a second trench; (d) etching a sidewall of the second trench to form a third trench including an undercut space; (e) forming a device isolation structure that fills the first, second and third trenches; (f) etching the semiconductor substrate of a gate region to form a recess; and (g) forming a gate that fills the recess.

Abstract: The invention provides a STI structure and method for forming the same. The STI structure includes a semiconductor substrate; a first trench embedded in the semiconductor substrate and filled up with a first dielectric layer; and a second trench formed on a top surface of the semiconductor substrate and interconnected with the first trench, wherein the second trench is filled up with a second dielectric layer, a top surface of the second dielectric layer is flushed with that of the semiconductor substrate, and the second trench has a width smaller than that of the first trench. The invention reduces dimension of divots and improves performance of the semiconductor device.

Abstract: The drain and source regions of a multiple gate transistor may be formed without an epitaxial growth process by using a placeholder structure for forming the drain and source dopant profiles and subsequently masking the drain and source areas and removing the placeholder structures so as to expose the channel area of the transistor. Thereafter, corresponding fins may be patterned and a gate electrode structure may be formed. Consequently, reduced cycle times may be accomplished due to the avoidance of the epitaxial growth process.

Abstract: An electrostatic discharge protection device, a method of manufacturing the same, and a method of testing the same. The electrostatic protection device includes a plurality of device isolation regions formed in a semiconductor substrate at a predetermined width and a predetermined depth that each sequentially increase from a circuit device formation region of the semiconductor substrate to a ground region of the semiconductor substrate, a plurality of gate electrodes formed over the semiconductor substrate in spaces between adjacent ones of the device isolation regions, and a plurality of source regions and drain regions formed in the semiconductor substrate at both lateral sides of the gate electrode.

Abstract: The invention is related to a semiconductor device with alternately arranged P-type and N-type thin semiconductor layers and method for manufacturing the same. For P-type device, the method includes trench formation, thermal oxide formation on trench sidewalls, N-type silicon formation in trenches, N-type impurity diffusion through thermal oxide into P-type epitaxial layer, oxidation of N-type silicon in trenches and oxide removal. In the semiconductor device, N-type thin semiconductor layers are formed by N-type impurity diffusion through oxide to P-type epitaxial layers, and trenches are filled with oxide. With this method, relatively low concentration impurity in high voltage device can be realized by current mass production process, and the device development cost and manufacturing cost are decreased.

Abstract: A semiconductor substrate structure for manufacturing integrated circuit devices includes a bulk substrate; a lower insulating layer formed on the bulk substrate, the lower insulating layer formed from a pair of separate insulation layers having a bonding interface therebetween; an electrically conductive layer formed on the lower insulating layer; an insulator with etch stop characteristics formed on the electrically conductive layer; an upper insulating layer formed on the etch stop layer; and a semiconductor layer formed on the upper insulating layer. A scheme of subsequently building a dual-depth shallow trench isolation with the deeper STI in the back gate layer self-aligned to the shallower STI in the active region in such a semiconductor substrate is also disclosed.

Abstract: A semiconductor apparatus according to the present invention has a P-type well and an N-type well, with impurity concentration of a high impurity concentration region deeper than the P-type well and the N-type well being from 1×1017 cm?3 to 1×1019 cm?3, and the apparatus comprises a first channel separating section for separating elements, and a depth of the first channel separating section is equal to or deeper than the high impurity concentration region.

Abstract: A semiconductor device and a method of fabricating the same are provided. The semiconductor device includes a semiconductor substrate in which a multi-depth trench is formed, the multi-depth trench including a shallow trench and a deep trench arranged below the shallow trench, a first dielectric material formed in partial area of the multi-depth trench, the first dielectric material including a slope in the shallow trench that extends upward from a corner where a bottom plane of the shallow trench and a sidewall of the deep trench meets, the slope being inclined with respect to the bottom plane of the shallow trench, and a second dielectric material formed in areas of the multi-depth trench in which the first dielectric material is absent.

Abstract: An isolation trench in a substrate of a semiconductor device includes a first shallow portion with a dielectric sidewall and a second deeper portion without a dielectric sidewall. The isolation trench is formed by forming a first shallow portion of the trench, forming dielectric sidewalls on the first shallow portion, and then etching the substrate below the first shallow portion to form the second deeper portion. Shallow isolation trenches may be formed simultaneously with the etching of the second deeper portion.

Abstract: A method of fabricating a semiconductor device including a vertical channel transistor. The method may include: forming a plurality of first device isolation layers in a substrate as a pattern of lines having a first depth from an upper surface of a substrate, to define a plurality of active regions, forming a plurality of trenches having a second depth smaller than the first depth, etching portions of the substrate that are under some of the plurality of trenches that are selected at a predetermined interval, to form a plurality of device isolation trenches having a third depth that is greater than the second depth, forming second device isolation layers that include an insulating material, in lower portions of the plurality of device isolation trenches, and forming buried bit lines in lower portions of the plurality of trenches and the plurality of device isolation trenches.

Abstract: A semiconductor device comprising a trench device isolation layer and a method for fabricating the semiconductor device are disclosed. The method comprises forming a plurality of first trenches on a first region of a semiconductor substrate, filling the first trenches with a first insulation material to form first device isolation layers, forming a plurality of second trenches on a second region of the semiconductor substrate, and filling the second trenches with a second insulation material different from the first insulation material to form second device isolation layers, wherein the first trenches and the second trenches are formed using different respective processes.

Abstract: The invention is directed to reduction of a manufacturing cost and enhancement of a breakdown voltage of a PN junction portion abutting on a guard ring. An N? type semiconductor layer is formed on a front surface of a semiconductor substrate, and a P type semiconductor layer is formed thereon. An insulation film is formed on the P type semiconductor layer. Then, a plurality of grooves, i.e., a first groove, a second groove and a third groove are formed from the insulation film to the middle of the N? type semiconductor layer in the thickness direction thereof. The plurality of grooves is formed so that one of the two grooves next to each other among these, that is closer to an electronic device, i.e., to an anode electrode, is formed shallower than the other located on the outside of the one. Then, an insulating material is deposited in the first groove, the second groove and the third groove. The lamination body of the semiconductor substrate and the layers laminated thereon is then diced along dicing lines.

Abstract: A method of fabricating a semiconductor device includes forming a well impurity region, a lower impurity region and an upper impurity region in a semiconductor substrate. The lower impurity region has a different conductivity type than a conductivity type of the well impurity region, the upper impurity region has a different conductivity type than the conductivity type of the lower impurity region, and the upper impurity region has a same conductivity type as the conductivity type of the well impurity region and has a higher impurity concentration than an impurity concentration of the well impurity region. The semiconductor substrate is etched to form lower semiconductor patterns, upper semiconductor patterns upwardly projecting from predetermined regions of the lower semiconductor patterns. An isolation layer filling the first and second spaces between the lower semiconductor patterns and between the upper semiconductor patterns, respectively is formed.

Abstract: A lithographic material stack including a photo-resist and an organic planarizing layer is combined with an etch process that generates etch residues over a wide region from sidewalls of etched regions. By selecting the etch chemistry that produces deposition of etch residues from the organic planarizing layer over a wide region, the etch residue generated at the sidewalls of the wide trench is deposited over the entire bottom surface of the wide trench. An etch residue portion remains at the bottom surface of the wide trench when the organic planarizing layer is etched through in the first trench region. The etch residue portion is employed in the next step of the etch process to retard the etch rate in the wide trench, thereby producing the same depth for all trenches in the material layer into which the pattern of the lithographic material stack is transferred.

Abstract: A method of manufacturing a non-volatile semiconductor memory device including previously forming a recess in a first peripheral region on a semiconductor substrate, forming a first gate insulator having a first thickness in the recess, forming a second gate insulator having a second thickness less than the first thickness in an array region and a second peripheral region on the semiconductor substrate, successively depositing first and second gate electrode films and first and second mask insulators on each of the first and second gate insulators, forming an isolation trench on a surface of the semiconductor substrate to correspond to each position between the array region and the first and second regions of the peripheral region, depositing a buried insulator on the entire surface, and polishing an upper surface of the buried insulator so that the upper surface can be planarized.

Abstract: In-situ semiconductor process that can fill high aspect ratio (typically at least 6:1, for example 7:1 or higher), narrow width (typically sub 0.13 micron, for example 0.1 micron or less) gaps without damaging underlying features and little or no incidence of voids or weak spots is provided. A protective layer is deposited to protect underlying features in regions of the substrate having lower feature density so that unwanted material may be removed from regions of the substrate having higher feature density. This protective layer may deposits thicker on a low density feature than on a high density feature and may be deposited using a PECVD process or low sputter/deposition ratio HDP CVD process. This protective layer may also be a metallic oxide layer that is resistant to fluorine etching, such as zirconium oxide (ZrO2) or aluminum oxide (Al2O3).

Abstract: In one embodiment, a two terminal multi-channel ESD device is configured to include a zener diode and a plurality of P-N diodes.

Abstract: A method of increasing etch rate during deep silicon dry etch by altering the geometric shape of the etch mask is presented. By slightly altering the shape of the etch mask, the etch rate is increased in one area where an oval etch mask is used as compared to another areas where different geometrically-shaped etch masks are used even though nearly the same amount of silicon is exposed. Additionally, the depth of the via can be controlled by using different geometrically-shaped etch masks while maintaining virtually the same size in diameter for all the vias.

Abstract: A variety of isolation structures for semiconductor substrates include a trench formed in the substrate that is filled with a dielectric material or filled with a conductive material and lined with a dielectric layer along the walls of the trench. The trench may be used in combination with doped sidewall isolation regions. Both the trench and the sidewall isolation regions may be annular and enclose an isolated pocket of the substrate. The isolation structures are formed by modular implant and etch processes that do not include significant thermal processing or diffusion of dopants so that the resulting structures are compact and may be tightly packed in the surface of the substrate.