Abstract: Selector devices that can be suitable for memory device applications can have low leakage currents at low voltages to reduce sneak current paths for non selected devices, and high leakage currents at high voltages to minimize voltage drops during device switching. The selector device can include a first electrode, a tri-layer dielectric layer, and a second electrode. The tri-layer dielectric layer can include a low band gap dielectric layer disposed between two higher band gap dielectric layers. The high band gap dielectric layers can be doped with doping materials to form traps at energy levels higher than the operating voltage of the memory device.

Abstract: A vertical semiconductor charge storage structure includes a substrate, at least one lower electrode, a dielectric layer and an upper electrode. The lower electrode includes a lower conductor, and a first side conductor and a second side conductor connected to the lower conductor. The first side conductor and the second side conductor are parallel to each other and form an included angle with the lower conductor. A height of the first side conductor from the substrate is greater than a height of the second side conductor from the substrate. The dielectric layer and the upper electrode are sequentially formed on surfaces of the substrate and the lower electrode. Accordingly, by forming the first side conductor and the second side conductor at different heights, an aperture ratio is increased to reduce difficulty in filling or deposition in subsequent processes to further enhance an overall yield rate.

Abstract: Methods and devices related to a plurality of high breakdown voltage embedded capacitors are presented. A semiconductor device may include gate material embedded in an insulator, a plurality of metal contacts, and a plurality of capacitors. The plurality of capacitors may include a lower electrode, a dielectric formed so as to cover a surface of the lower electrode, and an upper electrode formed on the dielectric. Further, the plurality of contacts may connect each of the lower electrodes of the plurality of capacitors to the gate material. The plurality of capacitors may be connected in series via the gate material.

Abstract: An integrated circuit includes isolation capacitors which include a silicon dioxide dielectric layer and a polymer dielectric layer over the layer of silicon dioxide. The silicon dioxide dielectric layer and the polymer dielectric layer extend across the integrated circuit. Top plates of the isolation capacitors have bond pads for wire bonds or bump bonds. Bottom plates of the isolation capacitors are connected to components of the integrated circuit. Other bond pads are connected to components in the integrated circuit through vias through the silicon dioxide dielectric layer and the polymer dielectric layer.

Abstract: Semiconductor devices including spacers on sidewalls of conductive lines are provided. The semiconductor device includes bit lines on a semiconductor substrate, a storage node contact plug penetrating an insulation layer between the bit lines, triple-layered bit line spacers between the bit lines and the storage node contact plugs, and storage node electrodes on the storage node contact plugs. Each of the triple-layered bit line spacers includes a first spacer adjacent to one of the bit lines, a third spacer adjacent to the storage node contact plugs and a second spacer between the first and third spacers. The second spacer includes a lower portion having a lower dielectric constant than the first and third spacers and an upper portion having the same material as the first and third spacers. Related methods are also provided.

Abstract: Integrated circuits with decoupling capacitor circuitry are provided. The decoupling capacitor circuitry may include density-compliance structures. The density-compliance structures may be strapped to metal paths driven by power supply lines. Strapping density-compliance dummy structures in this way may increase the capacitance per unit area of the decoupling capacitor circuitry. Strapping density-compliance dummy structures in this way may shield the decoupling capacitor from nearby noisy signal sources.

Abstract: A capacitor device includes a substrate including a first well having a first conductivity type and a first voltage applied thereto and a second well having a second conductivity type and a second voltage applied thereto; and a gate electrode disposed on an upper portion of the first well or an upper portion of the second well in such a way that the gate electrode is insulated from the first well or the second well, wherein capacitances of the capacitor device include a first capacitance between the first well and the second well and a second capacitance between the first well or the second well and the gate electrode.

Abstract: A transistor region of a first semiconductor layer and a capacitor region in the first semiconductor layer are isolated. A dummy gate structure is formed on the first semiconductor layer in the transistor region. A second semiconductor layer is formed on the first semiconductor layer. First and second portions of the second semiconductor layer are located in the transistor region, and a third portion of the second semiconductor layer is located in the capacitor region. First, second, and third silicide regions are formed on the first, second, and third portions of the second semiconductor layer, respectively. After forming a dielectric layer, the dummy gate structure is removed forming a first cavity. At least a portion of the dielectric layer located above the third silicide region is removed forming a second cavity. A gate dielectric is formed in the first cavity and a capacitor dielectric in the second cavity.

Abstract: A capacitor structure includes a conductive region; a first dielectric layer over the conductive region; a conductive material within the first dielectric layer, wherein the conductive material is on the conductive region and forms a first plate electrode of the capacitor structure; an insulating layer within the first dielectric layer and surrounding the conductive material; a first conductive layer within the first dielectric layer and surrounding the insulating layer, wherein the first conductive layer forms a second plate electrode of the capacitor structure; a second conductive layer laterally extending from the first conductive layer at a top surface of the first dielectric layer; a second dielectric layer over the first dielectric layer; and a third conductive layer within the second dielectric layer and on the conductive material.

Abstract: A capacitor structure includes a semiconductor substrate; a first capacitor plate positioned on the semiconductor substrate, the first capacitor plate including a polysilicon structure having a surrounding spacer; a silicide layer formed in a first portion of an upper surface of the first capacitor plate; a capacitor dielectric layer formed over a second portion of the upper surface of the first capacitor plate and extending laterally beyond the spacer to contact the semiconductor substrate; a contact in an interlayer dielectric (ILD), the contact contacting the silicide layer and a first metal layer over the ILD; and a second capacitor plate over the capacitor dielectric layer, wherein a metal-insulator-metal (MIM) capacitor is formed by the first capacitor plate, the capacitor dielectric layer and the second capacitor plate and a metal-insulator-semiconductor (MIS) capacitor is formed by the second capacitor plate, the capacitor dielectric layer and the semiconductor substrate.

Abstract: Methods and devices related to a plurality of high breakdown voltage embedded capacitors are presented. A semiconductor device may include gate material embedded in an insulator, a plurality of metal contacts, and a plurality of capacitors. The plurality of capacitors may include a lower electrode, a dielectric formed so as to cover a surface of the lower electrode, and an upper electrode formed on the dielectric. Further, the plurality of contacts may connect each of the lower electrodes of the plurality of capacitors to the gate material. The plurality of capacitors may be connected in series via the gate material.

Abstract: A semiconductor structure with high breakdown voltage and high resistance and method for manufacturing the same. The semiconductor structure at least comprises a substrate having a first conductive type; a deep well having a second conductive type formed in the substrate; two first wells having the first conductive type and formed within the deep well; a second well having the first conductive type and formed between the two first wells within the deep well, and an implant dosage of the second well lighter than an implant dosage of each of the two first wells; and two first doping regions having the first conductive type and respectively formed within the two first wells.

Abstract: Disclosed are integrated circuit structures each having a silicon germanium film incorporated as a local interconnect and/or an electrical contact. These integrated circuit structures provide improved local interconnects between devices and/or increased capacitance to devices without significantly increasing structure surface area or power requirements. Specifically, disclosed are integrated circuit structures that incorporate a silicon germanium film as one or more of the following features: as a local interconnect between devices; as an electrical contact to a device (e.g., a deep trench capacitor, a source/drain region of a transistor, etc.); as both an electrical contact to a deep trench capacitor and a local interconnect between the deep trench capacitor and another device; and as both an electrical contact to a deep trench capacitor and as a local interconnect between the deep trench capacitor and other devices.

Abstract: A semiconductor device is provided which includes a semiconductor substrate having a first region and a second region, transistors having metal gates formed in the first region, and at least one capacitor formed in the second region. The capacitor includes a top electrode having at least one stopping structure formed in the top electrode, the at least one stopping structure being of a different material from the top electrode, a bottom electrode, and a dielectric layer interposed between the top electrode and the bottom electrode.

Abstract: A semiconductor integrated circuit includes a first conduction-type semiconductor region, a second conduction-type first impurity region, and a guard ring formed using a first conduction-type second impurity region so as to form a protection device of an electrostatic protection circuit. The first impurity region is formed inside the semiconductor region to have a rectangular planar structure with long and short sides. The guard ring is formed inside the semiconductor region to surround the periphery of the first impurity region. A weak spot is formed on the short side of the rectangular planar structure of the first impurity region. A plurality of electrical contacts are formed in a first portion of the guard ring which faces the long side of the rectangle. A plurality of electrical contracts are not formed in a second portion of the guard ring which faces the weak spot formed on the short side of the rectangle.

Abstract: A semiconductor device with a dynamic gate drain capacitance. One embodiment provides a semiconductor device. The device includes a semiconductor substrate, a field effect transistor structure including a source region, a first body region, a drain region, a gate electrode structure and a gate insulating layer. The gate insulating layer is arranged between the gate electrode structure and the body region. The gate electrode structure and the drain region partially form a capacitor structure including a gate-drain capacitance configured to dynamically change with varying reverse voltages applied between the source and drain regions. The gate-drain capacitance includes at least one local maximum at a given threshold or a plateau-like course at given reverse voltage.

Abstract: Integrated circuits with decoupling capacitor circuitry are provided. The decoupling capacitor circuitry may include density-compliance structures. The density-compliance structures may be strapped to metal paths driven by power supply lines. Strapping density-compliance dummy structures in this way may increase the capacitance per unit area of the decoupling capacitor circuitry. Strapping density-compliance dummy structures in this way may shield the decoupling capacitor from nearby noisy signal sources.

Abstract: An object is to provide a demodulation circuit having a sufficient demodulation ability. Another object is to provide an RFID tag which uses a demodulation circuit having a sufficient demodulation ability. A material which enables a reverse current to be small enough, for example, an oxide semiconductor material, which is a wide bandgap semiconductor, is used in part of a transistor included in a demodulation circuit. By using the semiconductor material which enables a reverse current of a transistor to be small enough, a sufficient demodulation ability can be secured even when an electromagnetic wave having a high amplitude is received.

Abstract: A semiconductor device includes a substrate, an insulating film formed over the substrate, first and second conductive plugs formed in the insulating film, a capacitor element, and a wiring. The capacitor element includes a lower electrode, a dielectric film, and an upper electrode. The lower electrode is connected to an end of the first plug and formed on the insulating film, and includes a first barrier film. The dielectric film is formed on upper and side surfaces of the lower electrode. The upper electrode is formed on the dielectric film, and includes a second barrier metal film being wider than the lower electrode. The wiring is connected to an end of the second plug and formed on the insulating film, and includes a first layer and a second layer formed on the first layer. The first and second layers include the first and second barrier metal films, respectively.

Abstract: Disclosed are integrated circuit structures each having a silicon germanium film incorporated as a local interconnect and/or an electrical contact. These integrated circuit structures provide improved local interconnects between devices and/or increased capacitance to devices without significantly increasing structure surface area or power requirements. Specifically, disclosed are integrated circuit structures that incorporate a silicon germanium film as one or more of the following features: as a local interconnect between devices; as an electrical contact to a device (e.g., a deep trench capacitor, a source/drain region of a transistor, etc.); as both an electrical contact to a deep trench capacitor and a local interconnect between the deep trench capacitor and another device; and as both an electrical contact to a deep trench capacitor and as a local interconnect between the deep trench capacitor and other devices.

Abstract: A capacitor structure includes a semiconductor substrate; a first capacitor plate positioned on the semiconductor substrate, the first capacitor plate including a polysilicon structure having a surrounding spacer; a silicide layer formed in a first portion of an upper surface of the first capacitor plate; a capacitor dielectric layer formed over a second portion of the upper surface of the first capacitor plate and extending laterally beyond the spacer to contact the semiconductor substrate; a contact in an interlayer dielectric (ILD), the contact contacting the silicide layer and a first metal layer over the ILD; and a second capacitor plate over the capacitor dielectric layer, wherein a metal-insulator-metal (MIM) capacitor is formed by the first capacitor plate, the capacitor dielectric layer and the second capacitor plate and a metal-insulator-semiconductor (MIS) capacitor is formed by the second capacitor plate, the capacitor dielectric layer and the semiconductor substrate.

Abstract: A power source noise of a semiconductor device having a core cell configuring a logic circuit is reduced. Above the core cell configuring the logic circuit provided on a main surface of a semiconductor substrate are provided a first branch line for a first power source of the core cell, which is electrically connected to a first power source trunk line, and a second branch line for a second power source of the core cell, which is electrically connected to a second power source trunk line. The first and second branch lines are oppositely provided, thereby forming a capacitor between the first and second power sources.

Abstract: The present teachings relate to a method of forming a container capacitor structure on a substrate. In one embodiment, the method comprises etching a recess in the substrate, depositing a first conductive layer on the substrate so as to overlie the substrate and the recess, depositing a filler layer so as to overlie the first conductive layer and fill the recess, and etching the first and second conductive layers so as to define a lower electrode within the recess. The method further comprises forming a cap layer on the lower electrode so as to overlie the first conductive layer and the filler layer and etching at least a portion of the substrate away from the lower electrode to thereby at least partially isolate the lower electrode. Subsequently, the remainder of the capacitor structure may be formed by depositing a dielectric layer on the lower electrode and depositing a second conductive layer on the dielectric layer so as to form an upper electrode.

Abstract: A semiconductor device includes an isolated p-type well, wherein the isolated p-type well is a first electrode of a capacitor device; a capacitor dielectric on the isolated p-type well; a p-type polysilicon electrode over the capacitor dielectric, wherein the p-type polysilicon electrode is a second electrode of the capacitor device; a first p-type contact region in the isolated p-type well, laterally extending from a first sidewall of the p-type polysilicon electrode; a second p-type contact region in the isolated p-type well, laterally extending from a second sidewall of the p-type polysilicon electrode, opposite the first sidewall of the p-type polysilicon electrode, wherein a portion of the isolated p-type well between the first and second p-type contact regions is under the p-type polysilicon electrode and the capacitor dielectric; and an n-type isolation region surrounding the isolated p-type well. This device may be conveniently coupled to a fringe capacitor.

Abstract: A capacitor with a mixed structure of a Metal Oxide Semiconductor (MOS) capacitor and a Poly-silicon Insulator Poly-silicon (PIP) capacitor includes a substrate and a diffusion junction region formed over the substrate. A high concentration diffusion junction region may be formed in a portion of the diffusion junction region. An oxide layer may be formed over the substrate, the oxide layer having an opening that exposes a portion of the high concentration diffusion junction region. A first polysilicon plate may be formed over a portion of the oxide layer and spaced from the opening, and a nitride layer may be formed over a portion of the first polysilicon plate. A sidewall may be formed over a side of the first polysilicon layer, over a side of the nitride layer, and over a portion of the oxide layer between the side of the polysilicon layer and the opening. A second polysilicon plate may be formed over the nitride layer, over the sidewall, and over the high concentration diffusion junction region.

Abstract: An improvement for a smart, highside, high current, power switch module formed in an integrated circuit having at least one composite MOS/FET transistor switch connected to controlling and protection circuits. The power switch module has a load terminal (L), a battery input terminal (B), a control input terminal (C) and a diagnostic feedback terminal (M). The improvement provides overcurrent protection from a substantially instantaneous short circuit across an electrical load connected to the load terminal of the power switch module. The improvement is a capacitive circuit element connected between the battery input terminal (B) and the diagnostic feedback terminal (M).

Abstract: Provided is a semiconductor device that includes: a base insulating film 25 formed above a silicon substrate 10; a ferroelectric capacitor Q formed on the base insulating film 25; multiple interlayer insulating films 35, 48, and 62, and metal interconnections 45, 58, and 72 which are alternately formed on and above the capacitor Q; and conductive plugs 57 which are respectively formed inside holes 54a provided in the interlayer insulating films 48 and are electrically connected to the metal interconnections 45. In the semiconductor device, a first capacitor protection insulating film 50 is formed on an upper surface of the interlayer insulating film 48 by sequentially stacking a first insulating metal oxide film 50a, an intermediate insulating film 50b having a relative dielectric constant lower than that of the interlayer insulating film 48, and a second insulating metal oxide film 50c; and the holes 54a are also formed in the first capacitor protection insulating film 50.

Abstract: A semiconductor display device with an interlayer insulating film in which surface levelness is ensured with a limited film formation time, heat treatment for removing moisture does not take long, and moisture in the interlayer insulating film is prevented from escaping into a film or electrode adjacent to the interlayer insulating film. A TFT is formed and then a nitrogen-containing inorganic insulating film that transmits less moisture compared to organic resin film is formed so as to cover the TFT. Next, organic resin including photosensitive acrylic resin is applied and an opening is formed by partially exposing the organic resin film to light. The organic resin film where the opening is formed, is then covered with a nitrogen-containing inorganic insulating film which transmits less moisture than organic resin film does.

Abstract: This invention provides a capacitor device with a high dielectric constant material and multiple vertical electrode plates. The capacitor devices can be directly fabricated on a wafer with low temperature processes so as to be integrated with active devices formed on the wafer. This invention also forms vertical conducting lines in the capacitor devices using the through-silicon-via technology to facilitate the three-dimensional stacking of the capacitor devices.

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 capacitor for a semiconductor device having a dielectric film between an upper electrode and a lower electrode is featured in that the dielectric film includes an alternately laminated film of hafnium oxide and titanium oxide at an atomic layer level.

Abstract: A method for manufacturing a semiconductor device comprises: forming a lower electrode on a semiconductor substrate, sputtering a ferroelectric film on the lower electrode using a target, thermal treating the ferroelectric film in an atmosphere containing oxygen in accordance with an accumulated period of use of the target for fabricating the ferroelectric film, and forming an upper electrode on the ferroelectric film.

Abstract: According to an aspect of the present invention, there is provided a semiconductor memory including a lower electrode, a first insulating region formed in the same layer as the lower electrode, a ferroelectric film formed on the lower electrode and on the first insulating region, an upper electrode formed on the ferroelectric film, a second insulating region formed in the same layer as the upper electrode and a transistor. The first insulating region partitions the lower electrode. The second insulating region partitions the upper electrode. The transistor includes a first impurity region connected to the lower electrode and a second impurity region connected to the upper electrode. At least one of the first insulating region and the second insulating region is formed by insulating the lower electrode or the upper electrode.

Abstract: A semiconductor structure of a high side driver includes an ion-doped junction. The ion-doped junction includes a substrate and a deep well. The deep well is formed in the substrate and has a first concave structure. The ion-doped junction includes a semiconductor region connected to the first concave structure of the deep well and having substantially the same ion-doping concentration as the substrate.

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: Nanocrystalline forms of metal oxides, including binary metal oxide, perovskite type metal oxides, and complex metal oxides, including doped metal oxides, are provided. Methods of preparation of the nanocrystals are also provided. The nanocrystals, including uncapped and uncoated metal oxide nanocrystals, can be dispersed in a liquid to provide dispersions that are stable and do not precipitate over a period of time ranging from hours to months. Methods of preparation of the dispersions, and methods of use of the dispersions in forming films, are likewise provided. The films can include an organic, inorganic, or mixed organic/inorganic matrix. The films can be substantially free of all organic materials. The films can be used as coatings, or can be used as dielectric layers in a variety of electronics applications, for example as a dielectric material for an ultracapacitor, which can include a mesoporous material. Or the films can be used as a high-K dielectric in organic field-effect transistors.

Abstract: HfO2 films and ZrO2 films are currently being developed for use as capacitor dielectric films in 85 nm technology node DRAM. However, these films will be difficult to use in 65 nm technology node or later DRAM, since they have a relative dielectric constant of only 20-25. The dielectric constant of such films may be increased by stabilizing their cubic phase. However, this results in an increase in the leakage current along the crystal grain boundaries, which makes it difficult to use these films as capacitor dielectric films. To overcome this problem, the present invention dopes a base material of HfO2 or ZrO2 with an oxide of an element having a large ion radius, such as Y or La, to increase the oxygen coordination number of the base material and thereby increase its relative dielectric constant to 30 or higher even when the base material is in its amorphous state. Thus, the present invention provides dielectric films that can be used to form DRAM capacitors that meet the 65 nm technology node or later.

Abstract: The invention concerns a capacitor whereof one first electrode consists of a highly doped active region (D) of a semiconductor component (T) formed on one side of a surface of a semiconductor body, and whereof the second electrode consists of a conductive region (BR) coated with insulation (IL) formed beneath said active region and embedded in the semiconductor body.

Abstract: A method and apparatus for reducing parasitic capacitance. A P-well blocked layer is formed directly beneath a parasitic device. The P-well blocked layer significantly increases the resistance underneath the parasitic device. The resistance of the P-well blocked layer, in effect, partially disconnects the parasitic device from the ground terminal to minimize the effective capacitive impedance that is added to the total termination impedance.

Abstract: A semiconductor structure of a high side driver includes an ion-doped junction. The ion-doped junction includes a substrate, a first deep well and a second deep well, a first heavy ion-doped region and a second heavy ion-doped region. The first deep well and second deep well are formed in the substrate, which are separated but partially linked with each other, and the first deep well and the second deep well have the same ion-doped type. The first heavy ion-doped region is formed in the first deep well for connecting to a first high voltage, and the first heavy ion-doped region has the same ion-doped type as the first deep well. The second heavy ion-doped region is formed in the second deep well for connecting to a second high voltage, and the second heavy ion-doped region has the same ion-doped type as the first deep well.

Abstract: An integrated circuit package is provided. The package comprises a lid which is adapted to cover an integrated circuit, the lid is further adapted to provide bypass capacitance to the integrated circuit.

Abstract: The present invention provides a semiconductor device comprising a capacitive element with a very uniform capacitive value as well as a method of manufacturing the semiconductor device. In a capacitive element formation region 20 of a semiconductor device 1, an N-type well 22 as a conductive layer is formed in a surface layer of a P-type semiconductor substrate 10. A capacitive film 24 is deposited on a front surface of the semiconductor substrate 10 on which the N-type well 22 is formed. The part of front surface of the semiconductor substrate 10 in which the capacitive film 24 is deposited is substantially flat. An upper electrode 26 is provided on the capacitive film 24. The upper electrode 26 constitutes a capacitive element (on-chip capacitor) together with the N-type well 22, located opposite the upper electrode 26 across the capacitive film 24.

Abstract: An integrated circuit and method of forming an integrated circuit having a memory portion minimizes an amount of oxidation of nanocluster storage elements in the memory portion. A first region of the integrated circuit has non-memory devices, each having a control electrode or gate formed of a single conductive layer of material. A second region of the integrated circuit has a plurality of memory cells, each having a control electrode of at least two conductive layers of material that are positioned one overlying another. The at least two conductive layers are at substantially a same electrical potential when operational and form a single gate electrode. In one form each memory cell gate has two polysilicon layers overlying a nanocluster storage layer.

Abstract: A power semiconductor device that includes a passive component, e.g., a capacitor, mechanically and electrically coupled to at least one pole thereof.

Abstract: A capacitor structure is provided. The capacitor structure is configured in a substrate. The capacitor structure includes a plurality of electrode sets, at least a first conductive plug and at least a second conductive plug. The electrode sets correspond with each other and are disposed in different layers of the substrate. Each electrode set comprises a first electrode and a second electrode surrounding the former. In addition, the first conductive plug and the second conductive plug are disposed between two adjacent electrode sets. First electrodes of two adjacent electrode sets correspond with each other and are electrically connected to each other through the first conductive plug. Similarly, second electrodes of two adjacent electrode sets correspond with each other and are electrically connected to each other through the second conductive plug.

Abstract: Disclosed is a semiconductor device comprising a semiconductor substrate, a capacitor structure formed above the semiconductor substrate and comprising a first electrode, a second electrode provided below the first electrode, a third electrode provided below the second electrode, a first dielectric film provided between the first electrode and the second electrode, and a second dielectric film provided between the second electrode and the third electrode, an insulating film covering the capacitor structure and having a first hole reaching the first electrode, a second hole reaching the second electrode, and a third hole reaching the third electrode, a first conductive connection electrically connecting the first electrode and the third electrode and having portions buried in the first and third holes, and a second conductive connection formed separately from the first conductive connection and having a portion buried in the second hole.

Abstract: Methods are provided for fabricating semiconductor IC (integrated circuit) chips having high-Q on-chip capacitors formed on the chip back-side and connected to integrated circuits on the chip front-side using through-wafer interconnects. In one aspect, a semiconductor device includes a semiconductor substrate having a front side, a back side, and a buried insulating layer interposed between the front and back sides of the substrate. An integrated circuit is formed on the front side of the semiconductor substrate, an integrated capacitor is formed on the back side of the semiconductor substrate, and an interconnection structure is formed through the buried insulating layer to connect the integrated capacitor to the integrated circuit.

Abstract: A capacitor structure uses an aperture located within a dielectric layer in turn located over a substrate. A pair of conductor interconnection layers embedded within the dielectric layer terminates at a pair of opposite sidewalks of the aperture. A pair of capacitor plates is located upon the pair of opposite sidewalks of the aperture and contacting the pair of conductor interconnection layers, but not filling the aperture. A capacitor dielectric layer is located interposed between the pair of capacitor plates and filling the aperture. The pair of capacitor plates may be formed using an anisotropic unmasked etch followed by a masked trim etch. Alternatively, the pair of capacitor plates may be formed using an unmasked anisotropic etch only, when the pair of opposite sidewalks of the aperture is vertical and separated by a second pair of opposite sidewalks that is outward sloped.

Abstract: A charge pump circuit includes MOSFETs and MOS capacitors formed on the same substrate. Each of the MOS capacitors has a multiplicity of first electrodes formed in one region of the substrate, insulating layers formed on/above respective substrate regions between neighboring first electrodes, each layer covering at least the respective substrate region, and a multiplicity of second electrodes formed on/above the respective insulating layers. The MOS capacitors have improved frequency response.

Abstract: A thin-film device comprises a substrate and a capacitor provided on the substrate. The capacitor incorporates: a lower conductor layer; a dielectric film a portion of which is disposed on the lower conductor layer; and an upper conductor layer disposed on the dielectric film. The lower conductor layer has a top surface, a side surface, and a corner portion formed by the top and side surfaces. The upper conductor layer incorporates an upper electrode portion having a bottom surface opposed to the top surface of the lower conductor layer with the dielectric film disposed in between. When seen from above the upper conductor layer, the periphery of the bottom surface of the upper electrode portion is located inside the periphery of the top surface of the lower conductor layer without touching the periphery of the top surface of the lower conductor layer.