Abstract: First and second wells are formed in a semiconductor substrate. First and second trenches in the first second wells, respectively, each extend vertically and include a central conductor insulated by a first insulating layer. A second insulating layer is formed on a top surface of the semiconductor substrate. The second insulating layer is selectively thinned over the second trench. A polysilicon layer is deposited on the second insulating layer and then lithographically patterned to form: a first polysilicon portion over the first well that is electrically connected to the central conductor of the first trench to form a first capacitor plate, a second capacitor plate formed by the first well; and a second polysilicon portion over the second well forming a floating gate electrode of a floating gate transistor of a memory cell having an access transistor whose control gate is formed by the central conductor of the second trench.

Abstract: A semiconductor package including at least one functional die; at least one dummy die free of active circuit, wherein the dummy die comprises at least one metal-insulator-metal (MIM) capacitor; and a redistribution layer (RDL) structure interconnecting the MIM capacitor to the at least one functional die.

Abstract: A fingerprint sensor includes: a base substrate including a plurality of pixel regions; a sensing dielectric structure formed on the base substrate in the pixel regions; and a sensing connection structure formed in the sensing dielectric structure. The sensing dielectric structure exposes the sensing connection structure and the sensing connection structure is connected to the base substrate. The fingerprint sensor further includes a plurality of electrode plates formed on surfaces of the sensing dielectric structure and the sensing connection structure. A plurality of protrusions are formed on surfaces of the electrode plates. The fingerprint sensor further includes an insulation medium structure formed on the plurality of electrode plates.

Abstract: A semiconductor device for a volatile memory is disclosed. The semiconductor device includes a substrate, a side wall and an epitaxial liner. The substrate has a first height and is made of a first material having a first lattice parameter. The side wall defines a deep trench. The epitaxial liner is disposed around the side wall, is made of a second material having a second lattice parameter, and has a second height having a same level with the first height, wherein the epitaxial liner and the side wall cooperate for creating a desired aspect ratio for the deep trench.

Abstract: Semiconductor devices and methods are disclosed herein. In one example, a disclosed semiconductor device includes: an insulation layer, a first electrode with sidewalls and a bottom surface in contact with the insulation layer; a second electrode with sidewalls and a bottom surface in contact with the insulation layer; and an insulator formed between the first electrode and the second electrode. The insulator is coupled to a sidewall of the first electrode and coupled to a sidewall of the second electrode.

Abstract: The present disclosure, in some embodiments, relates to an integrated chip. The integrated chip includes a dielectric structure disposed over a substrate. A plurality of conductive interconnect layers are disposed within the dielectric structure. The plurality of conductive interconnect layers include alternating layers of interconnect wires and interconnect vias. A metal-insulating-metal (MIM) capacitor is arranged within the dielectric structure. The MIM capacitor has a lower conductive electrode separated from an upper conductive electrode by a capacitor dielectric structure. The MIM capacitor vertically extends past two or more of the plurality of conductive interconnect layers.

Abstract: An electrode for a Lithium battery, comprising: a multi-dyad nanolaminate stack formed of a metal oxide layer of the group TiO2, MnO2 or combinations thereof, ranging between 0.3 and 300 nm; separated by a decoupling layer.

Abstract: Method and apparatus for a capacitive structure. The capacitive structure includes a material stack having a deep trench formed therein. The material stack includes alternating vertical and semi-ovoid sidewall surfaces. The material stack further includes alternating metallization layers and dielectric layers. At least one of the semi-spheroidal sidewall surfaces is formed in a sidewall of at least one of the dielectric layers in the deep trench. At least one of the vertical sidewall surfaces is a sidewall surface of at least one metallization layer in the deep trench.

Abstract: A chip package includes a substrate, first and second dielectric layers, first and second metal layers, and first conductive vias. The first dielectric layer is on a bottom surface of the substrate. The first metal layer is on a bottom surface of the first dielectric layer. The first metal layer has first sections, and every two adjacent first sections have a gap therebetween. The second dielectric layer is on a bottom surface of the first metal layer and the bottom surface of the first dielectric layer. The second metal layer is on a bottom surface of the second dielectric layer, and has second sections respectively aligned with the gaps. Two sides of the second section respectively overlap two adjacent first sections. The first conductive via is in the second dielectric layer and in electrical contact with the first and second sections.

Abstract: A method of manufacturing a semiconductor device includes forming a first pattern structure having a first opening and a second pattern structure having a second opening on a substrate, forming a gap fill layer in the second opening, forming fences and contact structures in the first opening, removing the gap fill layer in the second opening, forming an upper conductive layer to cover the first and second pattern structures, the fences, and the contact structures, forming a mask pattern based on a photolithography process using the second pattern structure covered by the upper conductive layer as an align mark, and etching the upper conductive layer using the mask pattern to form upper conductive patterns. A width of the second opening is larger than a width of a first opening. A thickness of the upper conductive layer is smaller than a depth of the second opening.

Abstract: A capacitor includes a stack. The stack has a first metallic layer formed over a substrate, an insulator formed over the first metallic layer, and a second metallic layer formed over the insulator. The first metallic layer has at least one high domain and at least one low domain, where a surface of the substrate in the at least one low domain has a height that is lower than a surface of the substrate in the at least one high domain.

Abstract: A circuit layer for an integrated circuit card comprising an electronic circuit embedded in a substrate and a coating covering the substrate and circuit. To enable larger tolerances of the position of the circuit in the substrate, the electronic circuit has contact pads with a quadrangular shape and the contact pads are exposed through the coating by holes having a circular shape.

Abstract: A method of fabricating a semiconductor device includes: forming alternately a plurality of first films and a plurality of second films on a substrate, forming a hole in the first and second films, forming a first metal layer on a surface of the hole, and removing the first metal layer from a bottom of the hole. The method further includes forming a second metal layer on a surface of the first metal layer after removing the first metal layer from the bottom of the hole. The method further includes processing the bottom of the hole exposed from the first and second metal layers to increase a depth of the hole.

Abstract: A capacitor structure and method of forming the capacitor structure is provided, including a providing a doped region of a substrate having a two-dimensional trench array with a plurality of segments defined therein. Each of the plurality of segments has an array of a plurality of recesses extending along the substrate, where the plurality of segments are rotationally symmetric about a center of the two-dimensional trench array. A first conducting layer is presented over the surface and a bottom and sidewalls of the recesses and is insulated from the substrate by a first dielectric layer. A second conducting layer is presented over the first conducting layer and is insulated by a second dielectric layer. First and second contacts respectively connect to an exposed top surface of the first conducting layer and second conducting layer. A third contact connects to the substrate within a local region to the capacitor structure.

Abstract: A tool having a cutting edge that includes a sintered body containing cubic boron nitride. The sintered body integrally and inseparably includes an inner region and a binder phase enriched layer formed on at least part of a surface of the inner region. The inner region includes: 15-90 volume % of cubic boron nitride; and 10-85 volume % of a mixture of a binder phase and impurities. The binder phase enriched layer includes: 90-100 volume % of the binder phase and impurities mixture; and 0-10 volume % of cubic boron nitride; and the binder phase contains at least one kind selected from the group consisting of: at least one element selected from the group consisting of Ti, Zr, Hf, V, Nb, Ta, Cr, Mo, W, Al, Co, Ni and Si; and a compound of the element and at least one element selected from the group consisting of C, N, O and B.

Abstract: A capacitor includes an electrode assembly, having at least one positive electrode, at least one negative electrode, and at least one dielectric or separator interposed between the positive electrode and the negative electrode, and a case for receiving the electrode assembly. The electrode assembly is configured such that the positive electrode, the negative electrode, and the dielectric or the separator are arranged in a horizontal direction, which is perpendicular to the thickness direction of the electrode assembly, and such that the positive electrode and the negative electrode have a complementary pattern.

Abstract: A method of fabricating a semiconductor device is described. A plurality of first films and a plurality of second films are alternately formed on a substrate. A hole is formed in the first and second films. A first metal layer is formed on a surface of the hole. The first metal layer is removed from a bottom surface of the hole. A second metal layer may be formed on a surface of the first metal layer after removing the first metal layer from the bottom surface of the hole. The bottom of the hole exposed from the first and second metal layers may be processed to increase a depth of the hole.

Abstract: A ceramic electronic device includes: a ceramic main body that has at least two edge faces facing each other, has an internal electrode layer inside thereof and has a parallelepiped shape; and external electrodes formed on the two edge faces, wherein: the external electrodes have at least a plated layer; an oxide film of a metal for plating of the plated layer on a region that is a part of at least one of four side faces of the ceramic main body other than the two edge faces, the region not being covered with the external electrodes; and a ratio of (a peak area of an oxide of the metal for plating)/(a peak area of the metal for plating) is 13.1 or more in a photoelectron spectrum of an outermost surface of the oxide film.

Abstract: A capacitor component includes a multilayer structure including unit laminates. Each unit laminate has a plurality of internal electrodes and a first connecting electrode extending in a stacking direction of the plurality of internal electrodes and connected to portions of the plurality of internal electrodes. First connecting electrodes of unit laminates adjacent to each other among the unit laminates are connected to each other. A diameter of a first connecting electrode of at least one of the unit laminates is different from diameters of first connecting electrodes of other unit laminates.

Abstract: A semiconductor memory device includes, for example, a substrate having a fin having a web portion extending from the substrate and a first overhanging fin portion extending outward from the web portion and spaced from the substrate, the fin comprising a source/drain region in the web portion of the fin, a first source/drain region in the first overhanging fin portion, an isolation material surrounding the web portion and disposed under the first overhanging fin portion of the fin, an upper surface of the isolation material being below an upper surface of the fin, a first gate disposed over the fin between the source/drain region in the web portion of the fin and the first source/drain region in the first overhanging fin portion of the fin, and a capacitor operably electrically connected to the first source/drain region in the first overhanging fin portion.

Abstract: A capacitor includes a plurality of cells each including a capacitance formation portion in which a plurality of trenches are positioned and a margin portion disposed around the capacitance formation portion. The cell includes three or more dielectric layers disposed in the capacitance formation portion and extending in the trenches, and three or more electrode layers sequentially stacked with dielectric layers interposed therebetween and extending in the trenches. At least first and second electrode layers have opposite polarities and each include a lead electrode extending from the capacitance formation portion to the margin portion. A lead electrode of the first electrode layer is disposed in a first region disposed to one side of a central portion of a cell, and a lead electrode of the second electrode layer is disposed in a second region disposed on another side of a central portion of the cell.

Abstract: A capacitor structure and method of forming the capacitor structure is provided, including a providing a doped region of a substrate having a two-dimensional trench array with a plurality of segments defined therein. Each of the plurality of segments has an array of a plurality of recesses extending along the substrate, where the plurality of segments are rotationally symmetric about a center of the two-dimensional trench array. A first conducting layer is presented over the surface and a bottom and sidewalls of the recesses and is insulated from the substrate by a first dielectric layer. A second conducting layer is presented over the first conducting layer and is insulated by a second dielectric layer. First and second contacts respectively connect to an exposed top surface of the first conducting layer and second conducting layer. A third contact connects to the substrate within a local region to the capacitor structure.

Abstract: A semiconductor memory device includes, for example, a substrate having a fin having a web portion extending from the substrate and a first overhanging fin portion extending outward from the web portion and spaced from the substrate, the fin comprising a source/drain region in the web portion of the fin, a first source/drain region in the first overhanging fin portion, an isolation material surrounding the web portion and disposed under the first overhanging fin portion of the fin, an upper surface of the isolation material being below an upper surface of the fin, a first gate disposed over the fin between the source/drain region in the web portion of the fin and the first source/drain region in the first overhanging fin portion of the fin, and a capacitor operably electrically connected to the first source/drain region in the first overhanging fin portion.

Abstract: A method for fabricating a capacitor includes following steps: providing a substrate and a first conducting material layer which is disposed on the substrate; removing a part of the first conducting material layer to expose a part of the substrate to form a plurality of first inner electrodes, wherein the first inner electrodes are arranged along a first direction, and the adjacent first inner electrodes have an interval therebetween; forming a dielectric layer along a second direction by a chemical vapor deposition process, wherein the first direction is perpendicular to the second direction so that the dielectric layer covers the first inner electrodes and the exposed part of the substrate, and the dielectric layer does not fully fill the intervals; and forming a second conducting material layer to fill the intervals that are not fully filled by the dielectric layer to form a plurality of second inner electrodes.

Abstract: A metal-insulator-metal (MIM) capacitor includes, in cross-sectional view, a first metal plate, a second metal plate, a third metal plate, and high-k material contacting the first metal plate, the second metal plate, and the third metal plate, in a manner achieved by using a single etching/mask pattern for an etching and deposition process to form the second metal plate, the third metal plate, the high-k material layer, and contact with the first metal plate.

Abstract: A method of manufacturing a piezoelectric element includes a first electrode, a piezoelectric layer, and a second electrode, in which unevenness on one surface of the piezoelectric layer is formed by forming an oxidizable metal layer on the one surface of the piezoelectric layer; aggregating the metal layer by thermal oxidation; and performing isotropic etching on the metal layer aggregated on the one surface of the piezoelectric layer.

Abstract: After forming a recessed conductive material portion over a deep trench capacitor located in a lower portion of a deep trench embedded in a substrate, a hard mask layer is formed over a top semiconductor layer of the substrate and the recessed conductive material portion such that the hard mask layer completely fills the deep trench. Next, the hard mask layer, the top semiconductor layer and the recessed conductive material portion are patterned to form a laterally contacting pair of a semiconductor fin and a conductive strap structure over the deep trench capacitor as well as a dielectric cap embedded in the deep trench. The dielectric cap vertically contacts a lower portion of the conductive strap structure and laterally surrounds a portion of an upper portion of the conductive strap structure that is not in contact with the semiconductor fin.

Abstract: Provided is a method of manufacturing a capacitor of a display apparatus, the display apparatus being formed on a substrate and including a thin film transistor, which includes an active layer, a gate electrode, and source and drain electrodes, a display device connected to the thin film transistor, and the capacitor, the method including: forming an electrode layer on the substrate; forming a passivation layer on the electrode layer; patterning the passivation layer to form a first pattern including first branch patterns parallel to each other, and a second pattern including second branch patterns parallel to each other and interposed between the first branch patterns; and forming first and second electrodes by etching the electrode layer using the first and second patterns as masks.

Abstract: A production process for a micromechanical component includes at least partially structuring at least one structure from at least one monocrystalline silicon layer by at least performing a crystal-orientation-dependent etching step on an upper side of the silicon layer with a given (110) surface orientation of the silicon layer. For the at least partial structuring of the at least one structure, at least one crystal-orientation-independent etching step is additionally performed on the upper side of the silicon layer with the given (110) surface orientation of the silicon layer.

Abstract: A method of forming a capacitor includes depositing a dielectric metal oxide layer of a first phase to a thickness no greater than 75 Angstroms over an inner conductive capacitor electrode material. The first phase dielectric metal oxide layer has a k of at least 15. Conductive RuO2 is deposited over and into physical contact with the dielectric metal oxide layer. Then, the RuO2 and the dielectric metal oxide layer are annealed at a temperature below 500° C. The RuO2 in physical contact with the dielectric metal oxide during the annealing facilitates a change of the dielectric metal oxide layer from the first phase to a second crystalline phase having a higher k than the first phase. The annealed dielectric metal oxide layer is incorporated into a capacitor dielectric region of a capacitor construction. Other implementations are disclosed.

Abstract: A semiconductor device includes a substrate wafer and having a front face and a back face. A front hole is formed in the front face and a multilayer capacitor is formed in the front hole. A back hole is formed in the back face of the substrate wafer to expose at least a portion of the multilayer capacitor. A front electrical connection on the front face and a back electrical connection in the back hole are used to make electrical connection to first and second conductive plates of the multilayer capacitor which are separated by a dielectric layer. The front hole may have a cylindrical shape or an annular shape.

Abstract: A capacitive device includes a well, a first dielectric layer, a first conductive layer, a cap dielectric layer, and a first electrode. The well includes a first shoulder portion having an upper surface, a second shoulder portion having an upper surface, and a first trench, sandwiched between the first and second shoulder portions, having sidewalls and a bottom surfaces. The first dielectric layer is lined along at least a portion of the upper surfaces of the first and second shoulder portions, the sidewalls of the first trench, and the bottom surface of the first trench. The first conductive layer is lined along the first dielectric layer. The cap dielectric layer is over the well, the first dielectric layer, and the first conductive layer. The first electrode is in contact with the first shoulder portion.

Abstract: An interdigitated capacitor includes a substrate and a pair of comb-like electrodes both formed on the semiconductor substrate and horizontally arranged thereon, each of the pair of comb-like electrodes including finger electrodes having a curved profile.

Abstract: A semiconductor device may include, but is not limited to: a semiconductor substrate; a memory capacitor; and a first compensation capacitor. The semiconductor substrate has at least first and second regions. The memory capacitor is positioned over the first region. The memory capacitor may include, but is not limited to: a first lower electrode; and a first dielectric film covering inner and outer surfaces of the first lower electrode. The first compensation capacitor is positioned over the second region. The first compensation capacitor includes, but is not limited to: a second lower electrode; a second dielectric film covering an inner surface of the second lower electrode; and a first insulating film covering an outer surface of the second lower electrode.

Abstract: A capacitive device includes a well, a first dielectric layer, a first conductive layer, a cap dielectric layer, and a first electrode. The well includes a first shoulder portion having an upper surface, a second shoulder portion having an upper surface, and a first trench, sandwiched between the first and second shoulder portions, having sidewalls and a bottom surfaces. The first dielectric layer is lined along at least a portion of the upper surfaces of the first and second shoulder portions, the sidewalls of the first trench, and the bottom surface of the first trench. The first conductive layer is lined along the first dielectric layer. The cap dielectric layer is over the well, the first dielectric layer, and the first conductive layer. The first electrode is in contact with the first shoulder portion.

Abstract: An integrated capacitor includes a substrate with a first main surface area and an opposing second main surface area. A capacitor structure with a dielectric layer is integrated in the first main surface area. A compensation structure with a compensation layer is integrated in the second main surface area. The ratio between a surface enlargement of the second main surface area effected by the compensation structure corresponds to at least 30% of the surface enlargement of the first main surface area effected by the capacitor structure.

Abstract: A differential MOS capacitor includes a first plurality of upper capacitor plates, a second plurality of upper capacitor plates, and a conductive plate. At least two of the second plurality of upper capacitor plates are spaced laterally from each other and are disposed laterally between at least two of the first plurality of upper capacitor plates. The conductive plate is configured to serve as a common bottom capacitor plate such that a first capacitor is formed by the first plurality of upper capacitor plates and the conductive plate and a second capacitor is formed by the second plurality of upper capacitor plates and the conductive plate.

Abstract: A method for forming a trench capacitor includes providing a substrate of a semiconductor material having a hard mask layer; etching the hard mask layer and the substrate to form at least one trench extending into the substrate; and performing pull-back etching on the hard mask layer. In the pull-back etching, a portion of the hard mask layer defining and adjacent to side walls of an opening of the at least one trench is removed. A resulting opening on the hard mask layer has a width dimension larger than a width dimension of an opening of the at least one trench extending into the substrate. The method further comprises doping the semiconductor material defining upper surfaces and sidewalls of the at least one trench to form a doped well region.

Abstract: Partial removal of organic planarizing layer (OPL) material forms a plug of OPL material within an aperture that protects underlying material or electronic device such as a deep trench capacitor during other manufacturing processes. The OPL plug thus can absorb any differences or non-uniformity in, for example, etch rates across the chip or wafer and preserve recess dimensions previously formed. control of a lateral component of later removal of the OPL plug by etching also can increase tolerance of overlay error in forming connections and thus avoid loss in manufacturing yield.

Abstract: An electronic component manufacturing method that efficiently grinds a cover layer provided on a substrate even when the substrate is warped includes the step of forming first grooves at intervals in a cover layer provided on a substrate by repeating grinding with a rotary blade at a pitch more than a thickness W of the rotary blade. Next, at least portions provided in the cover layer along the first grooves are removed to reduce the thickness of the cover layer by repeating grinding at a pitch equal to or less than the thickness W of the rotary blade.

Abstract: An integrated FinFET and deep trench capacitor structure and methods of manufacture are disclosed. The method includes forming at least one deep trench capacitor in a silicon on insulator (SOI) substrate. The method further includes simultaneously forming polysilicon fins from material of the at least one deep trench capacitor and SOI fins from the SOI substrate. The method further includes forming an insulator layer on the polysilicon fins. The method further includes forming gate structures over the SOI fins and the insulator layer on the polysilicon fins.

Abstract: An improved semiconductor capacitor and method of fabrication is disclosed. A MIM stack, comprising alternating first-type and second-type metal layers (each separated by dielectric) is formed in a deep cavity. The entire stack can be planarized, and then patterned to expose a first area, and selectively etched to recess all first metal layers within the first area. A second selective etch is performed to recess all second metal layers within a second area. The etched recesses can be backfilled with dielectric. Separate electrodes can be formed; a first electrode formed in said first area and contacting all of said second-type metal layers and none of said first-type metal layers, and a second electrode formed in said second area and contacting all of said first-type metal layers and none of said second-type metal layers.

Abstract: A finger metal oxide metal (MOM) capacitor includes an outer conducting structure defined in a plurality of metal layers and a plurality of via layers of an integrated circuit. First and second side portions include a plurality of first and second finger sections extending in the plurality of metal layers and first and second hole vias connecting the first and second finger sections, respectively. A middle portion connects the first and second side portions. An inner conducting structure is defined in the plurality of metal layers and the plurality of via layers of the integrated circuit. A plurality of “T”-shaped sections are defined in the plurality of metal layers and third hole vias connecting the plurality of “T”-shaped sections. Middle portions of the plurality of “T”-shaped sections extend towards the middle portion and between the first side portion and the second side portion of the outer conducting structure.

Abstract: A method of manufacturing a capacitor includes forming a first ceramic film on a first base made of a metal, forming a second ceramic film on a second base made of a metal, forming a first copper electrode pattern and a first copper via-plug on a surface of one of the first and second ceramic films, the electrode pattern and the via-plug being separate from each other, bonding the first and second ceramic films together with the first electrode pattern and the via-plug therebetween, by applying a pulsed voltage between the first base and the second base while the first base and the second base are pressed so that the first ceramic film and the second ceramic film are pressed on each other, and removing the second base.

Abstract: A high-voltage metal capacitor with easy integration into existing semiconductor manufacturing processes can provide isolation capacitors up to several kilovolts. The capacitor includes a support layer with internal structure, including a lower place, a bond pad on the support layer, an upper plate disposed on the support layer, the upper plate being arranged above the lower plate, a dielectric layer, at least part of which is between the lower and upper plates, and a passivation layer, at least part of which covers at least part of the upper plate and part of the dielectric layer. A first opening extends from the surface through the passivation and dielectric layers to the lower plate, and a second opening extends from the surface through the passivation layer to the upper plate. A method of manufacturing the capacitor.

Abstract: Methods of forming and the resulting capacitors formed by these methods are shown. Monolayers that contain praseodymium are deposited onto a substrate and subsequently processed to form praseodymium oxide dielectrics. Monolayers that contain titanium or other metals are deposited onto a substrate and subsequently processed to form metal electrodes. Resulting capacitor structures includes properties such as improved dimensional control. One improved dimensional control includes thickness. Some resulting capacitor structures also include properties such as an amorphous or nanocrystalline microstructure. Selected components of capacitors formed with these methods have better step coverage over substrate topography and more robust film mechanical properties.

Abstract: Disclosed are an interdigitated capacitor and an interdigitated vertical native capacitor, each having a relatively low (e.g., zero) net coefficient of capacitance with respect to a specific parameter. For example, the capacitors can have a zero net linear temperature coefficient of capacitance (Tcc) to limit capacitance variation as a function of temperature or a zero net quadratic voltage coefficient of capacitance (Vcc2) to limit capacitance variation as a function of voltage. In any case, each capacitor can incorporate at least two different plate dielectrics having opposite polarity coefficients of capacitance with respect to the specific parameter due to the types of dielectric materials used and their respective thicknesses. As a result, the different dielectric plates will have opposite effects on the capacitance of the capacitor that cancel each other out such that the capacitor has a zero net coefficient of capacitance with respect to specific parameter.

Abstract: A horizontal metal-insulator-metal capacitor including a first metal spacer and a second metal spacer laterally separated by a dielectric material portion is provided within a single opening within at least one layer of dielectric material. A diffusion barrier material portion laterally separates sidewall surfaces of each metal spacer from a corresponding sidewall surface of the at least one layer of dielectric material provided by the opening. Each diffusion barrier material portion, each metal spacer and the dielectric material portion within the opening containing the horizontal metal-insulator-metal capacitor has a bottommost surface that is in contact with a recessed surface of the at least one layer of dielectric material.

Abstract: To provide a power storage device with improved cycle characteristics and a method for manufacturing the power storage device, a power storage device is provided with a conductive layer in contact with a surface of an active material layer including a silicon layer after an oxide film, such as a natural oxide film, which is formed on the surface of the active material layer is removed. The conductive layer is thus provided in contact with the surface of the active material layer including a silicon layer, whereby the conductivity of the electrode surface of the power storage device is improved; therefore, cycle characteristics of the power storage device can be improved.

Abstract: The present disclosure provides a deep trench capacitor device. A first capacitor electrode is made up of a doped region of semiconductor substrate in which two or more trenches are arranged. A second capacitor electrode is made up of a continuous body of conductive material. The continuous body of conductive material includes a lower body portion filling the two or more trenches and an upper body portion extending continuously over the lower body portion. The upper body portion extends upwardly out of the trenches by a non-zero distance. A capacitor dielectric liner is arranged in the two or more trenches to separate the first and second capacitor electrodes. The capacitor dielectric liner extends continuously out of the two or more trenches along outer sidewalls of the upper body portion.