Abstract: A substrate including a stack of a handle substrate, an optional lower insulator layer, a doped polycrystalline semiconductor layer, an upper insulator layer, and a top semiconductor layer is provided. A deep trench is formed through the top semiconductor layer, the upper insulator layer, and the doped polycrystalline semiconductor layer. Exposed vertical surfaces of the polycrystalline semiconductor layer are crystallographically etched to form random facets in the deep trench, thereby increasing the total exposed surface area of the polycrystalline semiconductor layer in the deep trench. A node dielectric and at least one conductive material are deposited to fill the trench and to form a buried strap portion, which constitute a capacitor of an eDRAM. Access transistors and other logic devices can be formed.

Abstract: A semiconductor integrated circuit device includes a substrate, a well structure within the substrate, a first region, a second region, and multiple isolation regions within the well structure. The device further includes a channel region within the first region, a gate dielectric layer overlying the channel region, and a gate stack overlying the gate dielectric layer, the gate stack includes a silicide layer overlying a polysilicon layer. The device additionally includes LDD structures on sides of the channel region and spacers on sides of the gate stack. Furthermore, the device includes a source region and a drain region and a contact structure over the source region, and a junction between the contact structure and the source region being within the second region.

Abstract: A method of forming a SOI substrate, diodes in the SOI substrate and electronic devices in the SOI substrate and an electronic device formed using the SOI substrate. The method of forming the SOI substrate includes forming an oxide layer on a silicon first substrate; ion-implanting hydrogen through the oxide layer into the first substrate, to form a fracture zone in the substrate; forming a doped dielectric bonding layer on a silicon second substrate; bonding a top surface of the bonding layer to a top surface of the oxide layer; thinning the first substrate by thermal cleaving of the first substrate along the fracture zone to form a silicon layer on the oxide layer to formed a bonded substrate; and heating the bonded substrate to drive dopant from the bonding layer into the second substrate to form a doped layer in the second substrate adjacent to the bonding layer.

Abstract: A semiconductor structure is disclosed. The semiconductor structure includes an active semiconductor layer, a semiconductor device having a gate disposed on top of the active semiconductor layer, and source and drain regions and a body/channel region disposed within the active semiconductor layer, an insulator layer having a first and second side, the first side being adjacent to the active semiconductor layer, a substrate disposed adjacent to the second side of the insulator layer, a deep trench capacitor disposed under the body/channel region of the semiconductor device. The deep trench capacitor electrically connects with and contacts the body/channel region of the semiconductor device, and is located adjacent to the gate of the semiconductor device. The semiconductor structure increases a critical charge Qcrit, thereby reducing a soft error rate (SER) of the semiconductor device.

Abstract: A semiconductor component includes a semiconductor body, in which are formed: a substrate of a first conduction type, a buried semiconductor layer of a second conduction type arranged on the substrate, and a functional unit semiconductor layer of a third conduction type arranged on the buried semiconductor layer, in which at least two semiconductor functional units arranged laterally alongside one another are provided. The buried semiconductor layer is part of at least one semiconductor functional unit, the semiconductor functional units being electrically insulated from one another by an isolation structure which permeates the functional unit semiconductor layer, the buried semiconductor layer, and the substrate. The isolation structure includes at least one trench and an electrically conductive contact to the substrate, the contact to the substrate being electrically insulated from the functional unit semiconductor layer and the buried layer by the at least one trench.

Abstract: The present disclosure provides on-chip decoupling capacitor structures having trench capacitors integrated with a passive capacitor formed in the back-end-of-line wiring to provide an improved overall capacitance density. In some embodiments, the structure includes at least one deep trench capacitor and a passive capacitor formed in at least two back-end-of-line wiring levels. The trench and passive capacitors are in electrical communication through one of the wiring levels. In other embodiments, the structure includes at least one deep trench capacitor, a first back-end-of-line wiring level, and a second back-end-of-line wiring level. The deep trench capacitor with a dielectric that has an upper edge that terminates at a lower surface of a shallow trench isolation region. The first wiring level is in electrical communication with the trench capacitor. The second wiring level is vertically electrically connected to the first wiring level by vertical connectors so as to form a passive capacitor.

Abstract: A wafer-scale multiple carbon nanotube transfer process is provided. According to one embodiment of the invention, plasma exposure processes are performed at various stages of the fabrication process of a carbon nanotube device or article to improve feasibility and yield for successive transfers of nanotubes. In one such carbon nanotube transfer process, a carrier material is partially etched by a plasma process before removing the carrier material through, for example, a wet etch. By applying the subject plasma exposure processes, fabrication of ultra-high-density nanotubes and ultra-high-density nanotube grids or fabrics is facilitated. The ultra-high-density nanotubes and ultra-high-density nanotube grids or fabrics fabricated utilizing embodiments of the invention can be used, for example, to make high-performance carbon nanotube field effect transistors (CNFETs) and low cost, highly-transparent, and low-resistivity electrodes for solar cell and flat panel display applications.

Abstract: A method for fabricating a reservoir capacitor of a semiconductor device where a first peripheral circuit region and a second peripheral circuit region are defined comprises: forming a gate on an upper portion of a semiconductor substrate of the second peripheral circuit region; forming an interlayer insulating film on the entire upper portion of the semiconductor substrate including the gate; etching the interlayer insulating film of the second peripheral circuit region to form a bit line contact hole; forming a bit line material and a sacrificial film on the upper portion of the interlayer insulating film including the bit line contact hole; and etching the sacrificial film of the first peripheral circuit region to form a trench that exposes the bit line material.

Abstract: A multi-dielectric film including at least one first dielectric film that is a composite film made of zirconium-hafnium-oxide and at least one second dielectric film that is a metal oxide film made of amorphous metal oxide. Adjacent ones of the dielectric films are made of different materials.

Abstract: A trench-type storage device includes a trench in a substrate (100), with bundles of carbon nanotubes (202) lining the trench and a trench conductor (300) filling the trench. A trench dielectric (200) may be formed between the carbon nanotubes and the sidewall of the trench. The bundles of carbon nanotubes form an open cylinder structure lining the trench. The device is formed by providing a carbon nanotube catalyst structure on the substrate and patterning the trench in the substrate; the carbon nanotubes are then grown down into the trench to line the trench with the carbon nanotube bundles, after which the trench is filled with the trench conductor.

Abstract: A method of making planar-type bottom electrode for semiconductor device is disclosed. A sacrificial layer structure is formed on a substrate. Multiple first trenches are defined in the sacrificial layer structure, wherein those first trenches are arranged in a first direction. The first trenches are filled with insulating material to form an insulating layer in each first trench. Multiple second trenches are defined in the sacrificial layer structure between the insulating layers, and are arranged in a second direction such that the second trenches intersect the first trenches. The second trenches are filled with bottom electrode material to form a bottom electrode layer in each second trench. The insulating layers separate respectively the bottom electrode layers apart from each other. Lastly, removing the sacrificial layer structure defines a receiving space by two adjacent insulating layers and two adjacent bottom electrode layers.

Abstract: A semiconductor device including a metallic compound Hfx1Moy1Nz1 as an electrode. The work function of the electrode can be modulated by doping the metallic compound with dopants including nitrogen, silicon or germanium. The metallic compound of the present invention is applicable to PMOS, NMOS, CMOS transistors and capacitors.

Abstract: A trench structure and a memory cell using the trench structure. The trench structure includes: a substrate; a trench having contiguous upper, middle and lower regions, the trench extending from a top surface of said substrate into said substrate; the upper region of the trench having a vertical sidewall profile; and the middle region of the trench having a tapered sidewall profile.

Abstract: A deep trench is formed to a depth midway into a buried insulator layer of a semiconductor-on-insulator (SOI) substrate. A top semiconductor layer is laterally recessed by an isotropic etch that is selective to the buried insulator layer. The deep trench is then etched below a bottom surface of the buried insulator layer. Ion implantation is performed at an angle into the deep trench to dope the sidewalls of the deep trench beneath the buried insulator layer, while the laterally recessed sidewalls of the top semiconductor layer are not implanted with dopant ions. A node dielectric and trench fill materials are deposited into the deep trench. A buried strap has an upper buried strap sidewall that is offset from a lower buried strap sidewall and a deep trench sidewall.

Abstract: An insulation structure is provided. The insulation structure includes a deep trench filled with silicon and disposed in a substrate, a first oxide layer serving as the insulation structure and disposed on the surface of the silicon in the deep trench, a first silicon layer disposed on the first oxide layer, a gate disposed on the first silicon layer and a shallow trench isolation adjacent to the deep trench.

Abstract: Techniques for manufacturing an electronic device. In certain embodiments, a substrate includes a lower patterned layer that has a target conductor. A hybrid-vertical contact may be disposed directly on the target conductor. The hybrid vertical contact may include a lower-vertical contact directly on the target conductor and an upper-vertical contact directly on the lower-vertical contact. The upper-vertical contact may have an upper width that is greater than a lower width of the lower-vertical contact.

Abstract: A method and structure for reducing cracks in a dielectric in contact with a metal structure. The metal structure comprises a first metal layer; a second metal layer disposed on, and in contact with the first metal layer, the second metal layer being stiffer than the first metal layer; a third metal layer disposed on, and in contact with the second metal layer, the second metal layer being stiffer than the third metal layer. An additional metal is included wherein the dielectric layer is disposed between the metal structure and the additional metal.

Abstract: A capacitor includes a substrate (110, 210), a first electrically insulating layer (120, 220) over the substrate, and a fin (130, 231) including a semiconducting material (135) over the first electrically insulating layer. A first electrically conducting layer (140, 810) is located over the first electrically insulating layer and adjacent to the fin. A second electrically insulating layer (150, 910) is located adjacent to the first electrically conducting layer, and a second electrically conducting layer (160, 1010) is located adjacent to the second electrically insulating layer. The first and second electrically conducting layers together with the second electrically insulating layer form a metal-insulator-metal stack that greatly increases the capacitance area of the capacitor. In one embodiment the capacitor is formed using what may be referred to as a removable metal gate (RMG) approach.

Abstract: A semiconductor device, having a memory cell region and a peripheral circuit region, includes an insulating film, having an upper surface, formed on a major surface of a semiconductor substrate to extend from the memory cell region to the peripheral circuit region. A capacitor lower electrode assembly is formed in the memory cell region to upwardly extend to substantially the same height as the upper surface of the insulating film on the major surface of the semiconductor substrate. Additionally, the lower electrode assembly includes first and second lower electrodes that are adjacent through the insulating film. A capacitor upper electrode is formed on the capacitor lower electrode through a dielectric film, to extend onto the upper surface of the insulating film. The capacitor lower electrode includes a capacitor lower electrode part having a top surface and a bottom surface.

Abstract: Disclosed are embodiments for a container capacitor structure in which at least two container capacitors, e.g., an inner and outer container capacitor, are made concentric and nested with respect to one another. The nested capacitors are formed in one embodiment by defining a hole in a dielectric layer for the nested container capacitors in the vicinity of two capacitor contact plugs. An outer capacitor plate is formed by etching back poly 1 to leave it substantially on the vertical edges of the hole and in contact with one of the plugs. At least one sacrificial sidewall is formed on the poly 1, and poly 2 is deposited over the sidewalls to form an inner capacitor plate in contact with the other plug. The structure is planarized, the sacrificial sidewalls are removed, a capacitor dielectric is formed, and is topped with poly 3. Additional structures such as a protective layer (to prevent poly 1-to-poly 2 shorting) and a conductive layer (to strap the plugs to their respective poly layers) can also be used.

Abstract: A semiconductor process and apparatus provide a high voltage deep trench capacitor structure (10) that is integrated in an integrated circuit, alone or in alignment with a fringe capacitor (5). The deep trench capacitor structure is constructed from a first capacitor plate (4) that is formed from a doped n-type SOI semiconductor layer (e.g., 4a-c). The second capacitor plate (3) is formed from a doped p-type polysilicon layer (3a) that is tied to the underlying substrate (1).

Abstract: A semiconductor device, having a memory cell region and a peripheral circuit region, includes an insulating film, having an upper surface, formed on a major surface of a semiconductor substrate to extend from the memory cell region to the peripheral circuit region. A capacitor lower electrode assembly is formed in the memory cell region to upwardly extend to substantially the same height as the upper surface of the insulating film on the major surface of the semiconductor substrate. Additionally, the lower electrode assembly includes first and second lower electrodes that are adjacent through the insulating film. A capacitor upper electrode is formed on the capacitor lower electrode through a dielectric film, to extend onto the upper surface of the insulating film. The capacitor lower electrode includes a capacitor lower electrode part having a top surface and a bottom surface.

Abstract: A high voltage semiconductor device, such as a RESURF transistor, having improved properties, including reduced on state resistance. The device includes a semiconductor substrate; a source region and a drain region provided in the substrate; wherein the source region and the drain region are laterally spaced from each other; and a drift region in the substrate between the source region and the drain region. The drift region includes a structure having at least two spaced trench capacitors extending between the source region and the drain region; and further includes a stack having at least a first region of a first conductivity type, a second region of a second conductivity type, and a third region of the first conductivity type, wherein the stack extends between the source region and the drain region and between the at least first and second trench capacitors and in electrical connection to the first and second trench capacitors.

Abstract: A semiconductor memory device has a first interlayer insulating film formed on a semiconductor substrate and having a capacitor opening portion provided in the film, and a capacitance element formed over the bottom and sides of the capacitor opening portion and composed of a lower electrode, a capacitance insulating film, and an upper electrode. A bit-line contact plug is formed through the first interlayer insulating film. At least parts of respective upper edges of the lower electrode, the capacitance insulating film, and the upper electrode at a side facing the bit-line contact plug are located below the surface of the first interlayer insulating film, the lower electrode, the capacitance insulating film, and the upper electrode being located over the sides of the capacitor opening portion. The upper electrode is formed over only the bottom and sides of the capacitor opening portion.

Abstract: The semiconductor memory device includes: an interlayer insulating film that is formed on a semiconductor substrate; an insulating film that is formed on the interlayer insulating film and has a cylinder hole; and a capacitor that has an impurity-containing silicon film, a lower metal electrode, a capacitive insulating film and an upper electrode, which are formed so as to cover a bottom and a side of the cylinder hole, wherein the cylinder hole extends through the insulating film so as to expose an end side of the contact plug, the end side facing opposite from the source electrode; and the impurity-containing silicon film has a silicide layer near an interface between the impurity-containing silicon film and the lower metal electrode, the silicide layer being produced by a reaction of impurity-containing silicon included in the impurity-containing silicon film with metal included in the lower metal electrode.

Abstract: A channel stop region is formed immediately under an STI, and thereafter, an ion implantation is performed with conditions in which an impurity is doped into an upper layer portion of an active region, and at the same time, the impurity is also doped into immediately under another STI, and a channel dose region is formed at the upper layer portion of the active region, and another channel stop region is formed immediately under the STI.

Abstract: A capacitor of a semiconductor memory of the present invention includes: a lower electrode which covers the surface of a storage node hole from the bottom to at least one of the sidewalls up to a level lower than the top surface of a second interlayer insulating film; a capacitive insulating film which covers the lower electrode; and an upper electrode which covers the capacitive insulating film.

Abstract: Disclosed are moveable microstructures comprising in-plane capacitive microaccelerometers, with submicro-gravity resolution (<200 ng/?Hz) and very high sensitivity (>17 pF/g). The microstructures are fabricated in thick (>100 ?m) silicon-on-insulator (SOI) substrates or silicon substrates using a two-mask fully-dry release process that provides large seismic mass (>10 milli-g), reduced capacitive gaps, and reduced in-plane stiffness. Fabricated devices may be interfaced to a high resolution switched-capacitor CMOS IC that eliminates the need for area-consuming reference capacitors. The measured sensitivity is 83 mV/mg (17 pF/g) and the output noise floor is ?91 dBm/Hz at 10 Hz (corresponding to an acceleration resolution of 170 ng/?Hz). The IC consumes 6 mW power and measures 0.65 mm2 core area.

Abstract: The present invention relates to a semiconductor device that contains a trench metal-insulator-metal (MIM) capacitor and a field effect transistor (FET), and a design structure including the semiconductor device embodied in a machine readable medium. The trench MIM capacitor comprises a first metallic electrode layer located over interior walls of a trench in a substrate, a dielectric layer located in the trench over the first metallic electrode layer, and a second metallic electrode layer located in the trench over the dielectric layer. The FET comprises a source region, a drain region, a channel region between the source and drain regions, and a gate electrode over the channel region. The trench MIM capacitor is connected to the FET by a metallic strap.

Abstract: A semiconductor process and apparatus provide a high voltage deep trench capacitor structure (10) that is integrated in an integrated circuit, alone or in alignment with a fringe capacitor (5). The deep trench capacitor structure is constructed from a first capacitor plate (4) that is formed from a doped n-type SOI semiconductor layer (e.g., 4a-c). The second capacitor plate (3) is formed from a doped p-type polysilicon layer (3a) that is tied to the underlying substrate (1).

Abstract: An isolated shallow trench isolation portion is formed in a top semiconductor portion of a semiconductor-on-insulator substrate along with a shallow trench isolation structure. A trench in the shape of a ring is formed around a doped top semiconductor portion and filled with a conductive material such as doped polysilicon. The isolated shallow trench isolation portion and the portion of a buried insulator layer bounded by a ring of the conductive material are etched to form a cavity. A capacitor dielectric is formed on exposed semiconductor surfaces within the cavity and above the doped top semiconductor portion. A conductive material portion formed in the trench and above the doped top semiconductor portion constitutes an inner electrode of a capacitor, while the ring of the conductive material, the doped top semiconductor portion, and a portion of a handle substrate abutting the capacitor dielectric constitute a second electrode.

Abstract: A small-size (w<0.5 micrometers) alignment mark in combination with a “k1 process” is proposed, which is particularly suited for the fabrication of trench-capacitor DRAM devices which requires highly accurate AA-DT and GC-DT overlay alignment. The “k1 process” is utilized to etch away polysilicon studded in the alignment mark trenches and to refresh the trench profile, thereby improving overlay alignment accuracy and precision.

Abstract: A capacitor structure including a substrate, a butting conductive layer, a second dielectric layer, a plurality of openings, a bottom electrode layer, a capacitor dielectric layer, a top electrode layer, and a second metal interconnect layer is provided. The substrate has a first dielectric layer and a first metal interconnect layer located in the first dielectric layer in a non-capacitor region. The butting conductive layer is disposed over the first dielectric layer in a capacitor region. The second dielectric layer is disposed over the first dielectric layer and covers the butting conductive layer. The openings include a first opening exposing a portion of the butting conductive layer and a second opening exposing the first metal interconnect layer. The bottom electrode layer, the capacitor dielectric layer, and the top electrode layer are conformally stacked in the first opening sequentially. The second metal interconnect layer is disposed in the openings.

Abstract: A semiconductor structure is described. The structure includes a trench opening formed in a semiconductor substrate having a semiconductor-on-insulator (SOI) layer and a buried insulating (BOX) layer; and a filling material formed in the trench opening, the filling material forming a “V” shape within the trench memory cell, wherein the “V” shape includes a top portion substantially adjacent to a top surface of the BOX layer. A method of fabricating the semiconductor structure is also described. The method includes forming a trench opening in a semiconductor substrate having an SOI layer and a BOX layer; laterally etching the BOX layer such that a portion of the trench opening associated with the BOX layer is substantially greater than a portion of the trench opening associated with the SOI layer; filling the trench opening with a filling material; and recessing the filling material.

Abstract: One embodiment of the present invention relates to a transistor that is at least partially formed in a semiconductor substrate having a surface. In particular, the transistor includes a first source/drain region, a second source/drain region, a channel region connecting said first and second source/drain regions. Said channel region is disposed in said semiconductor substrate. A channel direction is defined by a line connecting said first and said second source/drain regions. A gate groove is formed in said semiconductor substrate. Said gate groove is formed adjacent to said channel region. Said gate groove includes an upper portion and a lower portion, said upper portion being adjacent to said lower portion, and a gate dielectric layer disposed between said channel region and said gate groove.

Abstract: A semiconductor fabrication method. First, a semiconductor structure is provided. The semiconductor structure includes a semiconductor substrate, a trench in the semiconductor substrate. The trench includes a side wall which includes {100} side wall surfaces and {110} side wall surfaces. The semiconductor structure further includes a blocking layer on the {100} side wall surfaces and the {110} side wall surfaces. Next, portions of the blocking layer on the {110} side wall surfaces are removed without removing portions of the blocking layer on the {100} side wall surfaces such that the {110} side wall surfaces are exposed to a surrounding ambient.

Abstract: A method of fabricating an MIM type capacitor includes at least one of: Forming a first trench within an insulating interlayer formed on a semiconductor substrate. Forming a lower electrode layer of a metal nitride layer substance to fill an inside of the first trench. Forming a second trench on a surface of the lower electrode layer to have a depth less than the first trench. Forming a capacitor dielectric layer conformal along a surface of the lower electrode layer including the second trench. Forming an upper electrode layer of a metal nitride layer substance on the capacitor dielectric layer. Sequentially patterning the upper electrode layer and the capacitor dielectric layer by photolithography.

Abstract: A process for producing structures in a semiconductor zone, has the steps of a) producing a trench (2) in the semiconductor zone (18), b) filling the trench with a photoresist (19), and c) exposing the photoresist (19) using ion beams (20), d) developing the photoresist (19). The energy density and ion dose for the ion beams (20) are selected in such a way that the photoresist (19) is only chemically changed at defined depths, so as to produce two regions, in the first region (21) of which the photoresist has been chemically changed at the defined depths by the ion beams (20), and in the second region of which the photoresist has been left chemically unchanged, so that during the developing step the photoresist is removed in precisely one of the two regions.

Abstract: A design structure for capacitor having a suitably large value for decoupling applications is formed in a trench defined by isolation structures such as recessed isolation or shallow trench isolation. The capacitor provides a contact area coextensive with an active area and can be reliably formed individually or in small numbers. Plate contacts are preferably made through implanted regions extending to or between dopant diffused regions forming a capacitor plate. The capacitor can be formed by a process subsequent to formation of isolation structures such that preferred soft mask processes can be used to form the isolation structures and process commonality and compatibility constraint are avoided while the capacitor forming processes can be performed in common with processing for other structures.

Abstract: A method for forming a double sided container capacitor comprises forming a first capacitor top plate layer within a recess in a dielectric layer, then forming a first cell dielectric on the first top plate layer. Next, first and second bottom plate layers are formed on the first cell dielectric layer, and a second cell dielectric layer is formed on the second bottom plate layers. Finally, a second top plate layer is formed on the second cell dielectric layer, and the first and second top plate layers are electrically connected using a conductive plug or conductive spacer. An inventive structure formed using the inventive method is also described.

Abstract: A semiconductor structure having a plurality of gate stacks on a semiconductor substrate provided with a gate dielectric. The gate stacks have a lower first layer made of polysilicon, an overlying second layer made of a metal silicide, and an upper third layer made of an insulating material, and a sidewall oxide on the sidewalls of the first and second layers. The sidewall oxide is thinned or removed on one of the sidewalls, and the gate stacks have sidewall spacers made of the insulating material.

Abstract: A semiconductor structure is disclosed. The semiconductor structure includes an active semiconductor layer, a semiconductor device having a gate disposed on top of the active semiconductor layer, and source and drain regions and a body/channel region disposed within the active semiconductor layer, an insulator layer having a first and second side, the first side being adjacent to the active semiconductor layer, a substrate disposed adjacent to the second side of the insulator layer, a deep trench capacitor disposed under the body/channel region of the semiconductor device. The deep trench capacitor electrically connects with and contacts the body/channel region of the semiconductor device, and is located adjacent to the gate of the semiconductor device. The semiconductor structure increases a critical charge Qcrit, thereby reducing a soft error rate (SER) of the semiconductor device.

Abstract: A method of fabricating a bottle trench and a bottle trench capacitor. The method including: providing a substrate; forming a trench in the substrate, the trench having sidewalls and a bottom, the trench having an upper region adjacent to a top surface of the substrate and a lower region adjacent to the bottom of the trench; forming an oxidized layer of the substrate in the bottom region of the trench; and removing the oxidized layer of the substrate from the bottom region of the trench, a cross-sectional area of the lower region of the trench greater than a cross-sectional area of the upper region of the trench.

Abstract: A capacitor can prevent a problem of step coverage in semiconductor device, caused by a thickness of an insulator film and an upper metal film included a metal-insulator-metal (MIM) capacitor, between the MIM capacitor region and its circumferential region. A capacitor in a semiconductor device includes a first metal film provided with a recess having a predetermined depth over a semiconductor substrate. An insulator film and a second metal film may be formed in the recess with a thickness corresponding to a depth of the recess. The insulator and second metal films are disconnected from an inner lateral side of the recess. A dielectric film including a plurality of plugs is in contact with the first and second metal films and the insulator film. A plurality of metal electrodes is in contact with the plugs over the dielectric film.

Abstract: Double-sided container capacitors are formed using sacrificial layers. A sacrificial layer is formed within a recess in a structural layer. A lower electrode is formed within the recess. The sacrificial layer is removed to create a space to allow access to the sides of the structural layer. The structural layer is removed, creating an isolated lower electrode. The lower electrode can be covered with a capacitor dielectric and upper electrode to form a double-sided container capacitor.

Abstract: A deep trench is formed in a semiconductor substrate. The deep trench may comprise a pair of parallel substantially vertical sidewalls having a constant separation distance. A set of outer substantially vertical sidewalls may have a closed shape in a horizontal cross-section. At least one dielectric layer is formed in the deep trench. The deep trench is filled with at least one conductive trench fill material to form a conductive deep trench fill region. A shallow trench isolation structure is formed directly on the deep trench to encapsulate the conductive deep trench fill region therebeneath. The stack of the deep trench and the shallow trench isolation structure form a deep trench inter-well isolation structure that provides electrical isolation of devices on one side of the stack from devices on the other side.

Abstract: A method of forming an integrated circuit comprises: providing a semiconductor topography comprising an active transistor laterally adjacent to a trench capacitor formed in a semiconductor substrate, the active transistor comprising a source junction and a drain junction, wherein a barrier layer is disposed along a periphery of the trench capacitor for isolating the trench capacitor; forming an interlevel dielectric across the semiconductor topography; concurrently etching (i) a first opening through the interlevel dielectric to the drain junction of the active transistor and the trench capacitor, and (ii) a second opening through the interlevel dielectric to the source junction of the active transistor; and filling the first opening and the second opening with a conductive material to form a strap for electrically connecting the trench capacitor to the drain junction of the active transistor and to also form a contact for electrically connecting the source junction to an overlying level of the integrated cir

Abstract: A method for forming a semiconductor device is provided. The method includes providing a substrate having a plurality of protrusions projecting from the substrate; forming a silicon layer over the substrate and each protrusion; performing an anisotropic etching to transfer the silicon layer into a silicon spacer positioned on a side wall of each protrusion; forming an oxide layer over the silicon spacer; and etching the substrate to form a recess on the substrate by using the oxide layer as a mask.

Abstract: A dynamic random access memory structure includes a recessed-gate transistor disposed in the substrate; a trench capacitor structure disposed in the substrate and electrically connected to a first source/drain of the recessed-gate transistor; a first conductive structure disposed on and contacting the trench capacitor structure; a stack capacitor structure disposed on and contacting the first conductive structure, wherein a bottom electrode of the trench capacitor structure and a top electrode of the stack capacitor structure are electrically connected to serve as a common electrode; and a bit line disposed above a second source/drain of the recessed-gate transistor and electrically connected to the second source/drain, wherein the top of the bit line is lower than the top of the gate conductive layer of the recessed-gate transistor.

Abstract: A method of fabricating an image sensor which reduces fabricating costs through simultaneous formation of capacitor structures and contact structures may be provided. The method may include forming a lower electrode on a substrate, forming an interlayer insulating film on the substrate, the interlayer insulating film may have a capacitor hole to expose a first portion of the lower electrode.