Abstract: Openings are formed in first and second mask layers. Next, diameter of the opening in the second mask layer is enlarged so that the diameter of the opening in the second mask layer becomes larger by a length X than diameter of the opening in the first mask layer. Thereafter, mask material is formed into the opening in the second mask layer, to form a cavity with a diameter X within the opening in the second mask layer. There is formed a mask which includes the second mask layer and the mask material having therein opening including the cavity.

Abstract: The invention relates to a method for producing a solid electrolytic capacitor with excellent LC value, comprising sequentially stacking a dielectric oxide film, a semiconductor layer and an electrode layer on a sintered body of conductive powder to which an anode lead is connected and then encapsulating the whole with an outer jacket resin, wherein surface area of a cathode plate used in forming the semiconductor layer on the dielectric oxide film by applying current between the conductor having the dielectric oxide film thereon used as anode and the cathode plate provided in electrolysis solution is made larger by 10 times or more than its apparent surface area to thereby efficiently form the semiconductor layer, a capacitor produced by the method, and electronic circuits and electronic devices using the capacitor.

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: A dielectric wafer has, on top of its front face, a front electrical connection including an electrical connection portion. A blind hole passes through from a rear face of the wafer to at least partially reveal a rear face of the electrical connection portion. A through capacitor is formed in the blind hole. The capacitor includes a first conductive layer covering the lateral wall and the electrical connection portion (forming an outer electrode), a dielectric intermediate layer covering the first conductive layer (forming a dielectric membrane), and a second conductive layer covering the dielectric intermediate layer (forming an inner electrode). A rear electrical connection is made to the inner electrode.

Abstract: A memory device is provided that in one embodiment includes a trench capacitor located in a semiconductor substrate including an outer electrode provided by the semiconductor substrate, an inner electrode provided by a conductive fill material, and a node dielectric layer located between the outer electrode and the inner electrode; and a semiconductor device positioned centrally over the trench capacitor. The semiconductor device includes a source region, a drain region, and a gate structure, in which the semiconductor device is formed on a semiconductor layer that is separated from the semiconductor substrate by a dielectric layer. A first contact is present extending from an upper surface of the semiconductor layer into electrical contact with the semiconductor substrate, and a second contact from the drain region of the semiconductor device in electrical contact to the conductive material within the at least one trench.

Abstract: An through-substrate via fabrication method requires forming a through-substrate via hole in a semiconductor substrate, depositing an electrically insulating, continuous and substantially conformal isolation material onto the substrate and interior walls of the via using ALD, depositing a conductive material into the via and over the isolation material using ALD such that it is electrically continuous across the length of the via hole, and depositing a polymer material over the conductive material such that any continuous top-to-bottom openings present in the via holes are filled by the polymer material. The basic fabrication method may be extended to provide vias with multiple conductive layers, such as coaxial and triaxial vias.

Abstract: A capacitor structure in trench structures of a semiconductor device includes conductive regions made of metallic and/or semiconducting materials. The conducting regions are surrounded by a dielectric and form stacked layers in the trench structure of the semiconductor device.

Abstract: A method of forming a capacitor structure includes forming a pad oxide layer overlying a substrate, a nitride layer overlying the pad oxide layer, an interlayer dielectric layer overlying the nitride layer, and a patterned polysilicon mask layer overlying the interlayer dielectric layer. The method then applies a first RIE process to form a trench region through a portion of the interlayer dielectric layer using the patterned polysilicon mask layer and maintaining the first RIE to etch through a portion of the nitride layer and through a portion of the pad oxide layer. The method stops the first RIE when a portion of the substrate has been exposed. The method then forms an oxide layer overlying the exposed portion of the substrate and applies a second RIE process to continue to form the trench region by removing the oxide layer and removing a portion of the substrate to a predetermined depth.

Abstract: A memory device includes a mesa structure and a word line. The mesa structure, having two opposite side surfaces, includes at least one pair of source/drain regions and at least one channel base region corresponding to the pair of source/drain regions formed therein. The word line includes two linear sections and at least one interconnecting portion. Each linear section extends on the respective side surface of the mesa structure, adjacent to the channel base region. The at least one interconnecting portion penetrates through the mesa structure, connecting the two linear sections.

Abstract: A memory cell device has a bottom electrode and a top electrode, a plug of memory material in contact with the bottom electrode, and a cup-shaped conductive member having a rim that contacts the top electrode and an opening in the bottom that contacts the memory material. Accordingly, the conductive path in the memory cells passes from the top electrode through the conductive cup-shaped member, and through the plug of phase change material to the bottom electrode.

Abstract: A semiconductor capacitor with large area plates and a small footprint is formed on a semiconductor wafer by forming an opening in the wafer, depositing a first metal atoms through a first shadow mask that lies spaced apart from the wafer to form a first metal layer in the opening, a dielectric layer on the first metal layer, and a second metal atoms through a second shadow mask that lies spaced apart from the wafer to form a second metal layer on the dielectric layer.

Abstract: Provided are a semiconductor device and a method of fabricating the same. The semiconductor device includes a first interconnection disposed on a substrate. The interconnection includes a first silicon interconnection region and a first metal interconnection region sequentially stacked on the substrate. A second interconnection includes a second silicon interconnection region and a second metal interconnection region that are stacked sequentially. The second silicon interconnection region has a lower resistivity than the first silicon interconnection region.

Abstract: A method for forming a memory device in a semiconductor on insulator substrate is provided, in which a protective oxide that is present on the sidewalls of the trench protects the first semiconductor layer, i.e., SOI layer, of the semiconductor on insulator substrate during bottle etching of the trench. In one embodiment, the protective oxide reduces back channel effects of the transistors to the memory devices in the trench that are formed in the semiconductor on insulator substrate. In another embodiment, a thermal oxidation process increases the thickness of the buried dielectric layer of a bonded semiconductor on insulator substrate by oxidizing the bonded interface between the buried dielectric layer and at least one semiconductor layers of the semiconductor on insulator substrate. The increased thickness of the buried dielectric layer may reduce back channel effects in devices formed on the substrate having trench memory structures.

Abstract: A voltage converter includes an output circuit having a high-side device and a low-side device which can be formed on a single die (a “PowerDie”). The high-side device can include a lateral diffused metal oxide semiconductor (LDMOS) while the low-side device can include a trench-gate vertical diffused metal oxide semiconductor (VDMOS). The voltage converter can further include a controller circuit on a different die which can be electrically coupled to, and co-packaged with the output circuit.

Abstract: A semiconductor device includes a semiconductor substrate, an isolation structure disposed in the semiconductor substrate, a conductive layer disposed over the isolation structure, a capacitor disposed over the isolation structure, the capacitor including a top electrode, a bottom electrode, and a dielectric disposed between the top electrode and the bottom electrode, and a first contact electrically coupling the conductive layer and the bottom electrode, the bottom electrode substantially engaging the first contact on at least two faces.

Abstract: A device is provided that includes memory, logic and capacitor structures on a semiconductor-on-insulator (SOI) substrate. In one embodiment, the device includes a semiconductor-on-insulator (SOI) substrate having a memory region and a logic region. Trench capacitors are present in the memory region and the logic region, wherein each of the trench capacitors is structurally identical. A first transistor is present in the memory region in electrical communication with a first electrode of at least one trench capacitor that is present in the memory region. A second transistor is present in the logic region that is physically separated from the trench capacitors by insulating material. In some embodiments, the trench capacitors that are present in the logic region include decoupling capacitors and inactive capacitors. A method for forming the aforementioned device is also provided.

Abstract: An integrated circuit device includes a substrate with a first layer situated on the substrate. The first layer defines a first opening with a cover layer deposited on the first layer and coating a sidewall portion of the first opening. A second layer is situated on the cover layer. The second layer defines a second opening extending through the second layer and through the cover layer to connect the first and second openings.

Abstract: A method of manufacturing a semiconductor device includes forming silicon pillar 11 on substrate 10, forming a protective film which covers an upper end portion and a lower end portion of a side surface of silicon pillar 11, forming a constricted portion by anisotropic etching in a portion of the side surface of silicon pillar 11 which is not covered with the protective film after forming the protective film, removing the protective film after forming the constricted portion, forming gate oxide film 12 which covers the side surface of silicon pillar 11 in which the constricted portion is formed, and forming gate electrode 13 which covers gate oxide film 12.

Abstract: A single crystal silicon etching method includes providing a single crystal silicon substrate having at least one trench therein. The single crystal silicon substrate is exposed to an anisotropic etchant that undercuts the single crystal silicon. By controlling the length of the etch, single crystal silicon islands or smooth vertical walls in the single crystal silicon may be created.

Abstract: A method of fabricating a trench capacitor is provided in which a material composition of a semiconductor region of a substrate varies in a quantity of at least one component therein such that the quantity alternates with depth a plurality of times between at least two different values. For example, a concentration of a dopant or a weight percentage of a second semiconductor material in a semiconductor alloy can alternate between with depth a plurality of times between higher and lower values. In such method, the semiconductor region can be etched in a manner dependent upon the material composition to form a trench having an interior surface which undulates in a direction of depth from the major surface of the semiconductor region. Such method can further include forming a trench capacitor having an undulating capacitor dielectric layer, wherein the undulations of the capacitor dielectric layer are at least partly determined by the undulating interior surface of the trench.

Abstract: The invention includes semiconductor constructions, and also includes methods of forming pluralities of capacitor devices. An exemplary method of the invention includes forming conductive storage node material within openings in an insulative material to form conductive containers. A retaining structure lattice is formed in physical contact with at least some of the containers, and subsequently the insulative material is removed to expose outer surfaces of the containers. The retaining structure can alleviate toppling or other loss of structural integrity of the container structures. The electrically conductive containers correspond to first capacitor electrodes. After the outer sidewalls of the containers are exposed, dielectric material is formed within the containers and along the exposed outer sidewalls. Subsequently, a second capacitor electrode is formed over the dielectric material. The first and second capacitor electrodes, together with the dielectric material, form a plurality of capacitor devices.

Abstract: A method for forming a memory device in a semiconductor on insulator substrate is provided, in which a protective oxide that is present on the sidewalls of the trench protects the first semiconductor layer, i.e., SOI layer, of the semiconductor on insulator substrate during bottle etching of the trench. In one embodiment, the protective oxide reduces back channel effects of the transistors to the memory devices in the trench that are formed in the semiconductor on insulator substrate. In another embodiment, a thermal oxidation process increases the thickness of the buried dielectric layer of a bonded semiconductor on insulator substrate by oxidizing the bonded interface between the buried dielectric layer and at least one semiconductor layers of the semiconductor on insulator substrate. The increased thickness of the buried dielectric layer may reduce back channel effects in devices formed on the substrate having trench memory structures.

Abstract: A capacitor is described which includes a substrate with a doped area of the substrate forming a first electrode of the capacitor. A plurality of trenches is arranged in the doped area of the substrate, the plurality of trenches forming a second electrode of the capacitor. An electrically insulating layer is arranged between each of the plurality of trenches and the doped area for electrically insulating the trenches from the doped area. The doped area includes first open areas and at least one second open area arranged between neighboring trenches of the plurality of trenches, wherein the at least one open area is arranged below the at least one substrate contact. A shortest first distance between neighboring trenches is separated by the first open areas and is shorter than a shortest second distance between neighboring trenches separated by the at least one second open area.

Abstract: Trench capacitors and methods of manufacturing the trench capacitors are provided. The trench capacitors are very dense series capacitor structures with independent electrode contacts. In the method, a series of capacitors are formed by forming a plurality of insulator layers and a plurality of electrodes in a trench structure, where each electrode is formed in an alternating manner with each insulator layer. The method further includes planarizing the electrodes to form contact regions for a plurality of capacitors.

Abstract: One or more embodiments relate to a method of forming a semiconductor structure, comprising: providing a semiconductor substrate; forming an opening within the substrate; forming a conductive layer within the opening; and forming a semiconductor layer over the conductive layer.

Abstract: A dual node dielectric trench capacitor includes a stack of layers formed in a trench. The stack of layers include, from bottom to top, a first conductive layer, a first node dielectric layer, a second conductive layer, a second node dielectric layer, and a third conductive layer. The dual node dielectric trench capacitor includes two back-to-back capacitors, which include a first capacitor and a second capacitor. The first capacitor includes the first conductive layer, the first node dielectric layer, the second conductive layer, and the second capacitor includes the second conductive layer, the second node dielectric layer, and the third conductive layer. The dual node dielectric trench capacitor can provide about twice the capacitance of a trench capacitor employing a single node dielectric layer having a comparable composition and thickness as the first and second node dielectric layers.

Abstract: A conductive film is formed to extend from a bottom and a sidewall of a recess formed in an interlayer insulating film onto a top surface of the interlayer insulating film. Dry etching of the conductive film is performed such that a portion of the conductive film remains on the bottom and sidewall of the recess. The dry etching is also performed such that a deposition film is formed on a top portion of the recess.

Abstract: A nonvolatile ferroelectric memory device includes a plurality of unit cells. Each of the unit cells includes a cell capacitor and a cell transistor. The cell capacitor includes a storage node, a ferroelectric layer, and a plate line. The cell capacitors of more than one of the plurality of unit cells are provided in a trench.

Abstract: A semiconductor device is described includes a wiring layer, an insulating layer stacked on the wiring layer, a trench formed by digging down the insulating layer from the surface thereof, a film-shaped lower electrode formed along the inner surface of the trench, a capacitor film formed along the surface of the lower electrode, and an upper electrode opposed to the lower electrode with the capacitor film sandwiched therebetween.

Abstract: A semiconductor device for preventing the leaning of storage nodes and a method of manufacturing the same is described. The semiconductor device includes support patterns that are formed to support a plurality of cylinder type storage nodes. The support patterns are formed of a BN layer and have a hexagonal structure. The BN layer forming the support patterns has compressive stress as opposed to tensile stress and can therefore withstand cracking in the support patterns.

Abstract: A structure and a method for fabrication of the structure use a capacitor trench for a trench capacitor and a resistor trench for a trench resistor. The structure is typically a semiconductor structure. In a first instance, the capacitor trench has a linewidth dimension narrower than the resistor trench. The trench linewidth difference provides an efficient method for fabricating the trench capacitor and the trench resistor. In a second instance, the trench resistor comprises a conductor material at a periphery of the resistor trench and a resistor material at a central portion of the resistor trench.

Abstract: In accordance with aspects of the invention, a method of forming a memory cell is provided, the method including forming a steering element above a substrate, and forming a memory element coupled to the steering element, wherein the memory element comprises a carbon-based material having a thickness of not more than ten atomic layers. The memory element may be formed by repeatedly performing the following steps: forming a layer of a carbon-based material, the layer having a thickness of about one monolayer, and subjecting the layer of carbon-based material to a thermal anneal. Other aspects are also described.

Abstract: The invention is related to a memory device, including a substrate, a capacitor which is substantially C-shaped in a cross section parallel to the substrate surface and a word line coupling the capacitor. In an embodiment, the C-shaped capacitor is a deep trench capacitor, and in alternative embodiment, the C-shaped capacitor is a stack capacitor. Both inner edge and outer edge of the C-shaped capacitor can be used for providing capacitance.

Abstract: Micromodules and methods of making them are disclosed. An exemplary micromodule includes a substrate having a thin film inductor, and a bumped die mounted on the substrate and over the thin film inductor.

Abstract: An SOI layer has an initial trench extending therethrough, prior to deep trench etch. An oxidation step, such as thermal oxidation is performed to form a band of oxide on an inner periphery of the SOI layer to protect it during a subsequent RIE step for forming a deep trench. The initial trench may stop on BOX underlying the SOI. The band of oxide may also protect the SOI during buried plate implant or gas phase doping.

Abstract: An embedded memory system includes an array of dynamic random access memory (DRAM) cells, on the same substrate as an array of logic transistors. Each DRAM cell includes an access transistor and a capacitor structure. The capacitor structure is fabricated by forming a metal-insulator-metal capacitor in a dielectric layer.

Abstract: In one exemplary embodiment, a semiconductor structure including: a silicon-on-insulator substrate having of a top silicon layer overlying an insulation layer, where the insulation layer overlies a bottom silicon layer; a capacitor disposed at least partially in the insulation layer; a device disposed at least partially on the top silicon layer, where the device is coupled to a doped portion of the top silicon layer; a backside strap of first epitaxially-deposited material, where at least a first portion of the backside strap underlies the doped portion of the top silicon layer, where the backside strap is coupled to the doped portion of the top silicon layer at a first end of the backside strap and to the capacitor at a second end of the backside strap; and second epitaxially-deposited material that at least partially overlies the doped portion of the top silicon layer, where the second epitaxially-deposited material further at least partially overlies the first portion of the backside strap.

Abstract: Disclosed herein is a method of fabricating a capacitor of a semiconductor device that includes sequentially forming an interlayer insulating film defining a contact plug, a lower electrode oxide film, and a hard mask film over a semiconductor substrate; etching the hard mask film with a mask comprising a dummy pattern and a cell pattern to form a hard mask pattern wherein a first trench is formed in a dummy pattern region and a second trench is formed in a cell pattern region; forming a capping film that buries the first trench; and etching the lower electrode oxide film with the capping film and the hard mask pattern as a mask to form a lower electrode trench that exposes the contact plug.

Abstract: A method of making a semiconductor structure includes forming at least a first trench and a second trench having different depths in a substrate, forming a capacitor in the first trench, and forming a via in the second trench. A semiconductor structure includes a capacitor arranged in a first trench formed in a substrate and a via arranged in a second trench formed in the substrate. The first and second trenches have different depths in the substrate.

Abstract: A structure and method is provided for fabricating isolated capacitors. The method includes simultaneously forming a plurality of deep trenches and one or more isolation trenches surrounding a group or array of the plurality of deep trenches through a SOI and doped poly layer, to an underlying insulator layer. The method further includes lining the plurality of deep trenches and one or more isolation trenches with an insulator material. The method further includes filling the plurality of deep trenches and one or more isolation trenches with a conductive material on the insulator material. The deep trenches form deep trench capacitors and the one or more isolation trenches form one or more isolation plates that isolate at least one group or array of the deep trench capacitors from another group or array of the deep trench capacitors.

Abstract: A semiconductor device comprises: a semiconductor substrate including an active region defined as a device isolation film; a bit line hole disposed over the top portion of the semiconductor substrate; an oxide film disposed at sidewalls of the bit line hole; and a bit line conductive layer buried in the bit line hole including the oxide film. A bit line spacer is formed with an oxide film, thereby reducing a parasitic capacitance. A storage node contact is formed to have a line type, thereby securing a patterning margin. A storage node contact plug is formed with polysilicon having a different concentration, thereby reducing leakage current.

Abstract: A method for manufacturing a capacitor bottom electrode of a dynamic random access memory is provided. The method comprises providing a substrate having a memory cell region and forming a polysilicon template layer on the memory cell region of the substrate. A supporting layer is formed on the polysilicon template layer and plural openings penetrating through the supporting layer and the polysilicon template layer are formed and a liner layer is formed on at least a portion of the polysilicon template layer exposed by the openings A conductive layer substantially conformal to the substrate is formed on the substrate. A portion of the conductive layer on the supporting layer is removed so as to form plural capacitor bottom electrodes. Using the polysilicon template layer, the openings with relatively better profiles are formed and the dimension of the device can be decreased.

Abstract: An electronic device (ICD) comprises an integrated circuit (AIC) and a capacitance element (PIC). The integrated circuit (AIC) is provided with a plurality of circuit contact pairs (CI). The capacitance element (PIC) is provided with a plurality of capacitance contact pairs (CC). A capacitance is present between each of at least part of the capacitance contact pairs (CC). The plurality of capacitance contact pairs (CC) faces the plurality of circuit contact pairs (CI). At least a part of the capacitance contact pairs (CC) is electrically coupled in a pair-by-pair manner to at least a part of the circuit contact pairs (CI).

Abstract: A fabrication method which forms vertical capacitors in a substrate. The method is preferably an all-dry process, comprising forming a through-substrate via hole in the substrate, depositing a first conductive material layer into the via hole using atomic layer deposition (ALD) such that it is electrically continuous across the length of the via hole, depositing an electrically insulating, continuous and substantially conformal isolation material layer over the first conductive layer using ALD, and depositing a second conductive material layer over the isolation material layer using ALD such that it is electrically continuous across the length of the via hole. The layers are arranged such that they form a vertical capacitor. The present method may be successfully practiced at temperatures of less than 200° C., thereby avoiding damage to circuitry residing on the substrate that might otherwise occur.

Abstract: Crystallization-inducing metal elements are introduced onto an amorphous silicon thin film. A first, low-temperature, heat-treatment induces nucleation of metal-induced crystallization (MIC), resulting in the formation of small polycrystalline silicon “islands”. A metal-gettering layer is formed on the resulting partially crystallized thin film. A second, low-temperature, heat-treatment completes the MIC process, whilst gettering metal elements from the partially crystallized thin film. The process results in the desired polycrystalline silicon thin film.

Abstract: Methods of etching into silicon oxide-containing material with an etching ambient having at least 75 volume percent helium. The etching ambient may also include carbon monoxide, O2 and one or more fluorocarbons. The openings formed in the silicon oxide-containing material may be utilized for fabrication of container capacitors, and such capacitors may be incorporated into DRAM.

Abstract: A trench and method of fabrication is disclosed. The trench shape is cylindrosymmetric, and is created by forming a dopant profile that is monotonically increasing in dopant concentration level as a function of depth into the substrate. A dopant sensitive etch is then performed, resulting in a trench shape providing increased surface area, yet having relatively smooth trench walls.

Abstract: A semiconductor chip includes a substrate including a surface, an active transistor region and a substrate contact region formed on the substrate, a shallow trench isolation (STI) area formed in the surface and disposed at least partially between the active transistor region and the substrate contact region, and at least one capacitor at least partially buried in the STI area.

Abstract: An improved trench capacitor and method of fabrication are disclosed. The trench capacitor utilizes a rare-earth oxide layer to reduce depletion effects, thereby improving performance of the trench capacitor.

Abstract: A method for manufacturing a semiconductor device includes forming a first interlayer insulating film over a semiconductor substrate; forming a first opening in the first interlayer insulating film; forming a second interlayer insulating film on the first interlayer insulating film such that the first opening is not filled; and forming a second opening in the second interlayer insulating film such that the second opening is connected to the first opening.