Abstract: A method of manufacturing a semiconductor device includes forming an active fin extending longitudinally in a first direction along a surface of a substrate, forming a field insulating layer on the substrate, the field insulating layer covering a part of the active fin, forming a dummy gate electrode on the field insulating layer and the active fin, the dummy gate electrode extending in a second direction different from the first direction, forming a spacer on the sides of the dummy gate electrode, and removing the dummy gate electrode by a wet etching process that includes rinsing the dummy gate electrode intermittently during an etching away of the dummy gate electrode.

Abstract: A method of manufacturing a semiconductor device includes forming grooves in a first dielectric layer on a substrate, the first dielectric layer including a first part between the grooves, forming a first barrier layer and an interconnect layer in each groove, recessing the interconnect layer and the first barrier layer, forming a capping pattern on the recessed interconnect layer, etching at least a portion of the first part by a first etching process, sequentially etching the capping pattern and the at least a portion of the IMD part by a second etching process to form a trench, conformally forming a second barrier layer in the trench and on the recessed interconnection layer, and forming a second dielectric layer on the second barrier layer not to fill the trench such that an air gap is formed in the trench.

Abstract: Described herein are precursors and methods for forming silicon-containing films.

Abstract: A self-balanced diode device includes a substrate, a doped well, at least one first conductivity type heavily doped fin and at least two second conductivity type heavily doped fins. The doped well is arranged in the substrate. The first conductivity type heavily doped fin is arranged in the doped well, arranged in a line along a first direction, and protruded up from a surface of the substrate. The second conductivity type heavily doped fins is arranged in the doped well, arranged in a line along a second direction intersecting the first direction, respectively arranged at two opposite sides of the first conductivity type heavily doped fin, and protruded up from the surface of the substrate. Each second conductivity type heavily doped fin and the first conductivity type heavily doped fin are spaced at a fixed interval.

Abstract: Integrated circuits and methods of producing such integrated circuits are provided. In an exemplary embodiment, an integrated circuit includes a substrate with an active layer overlying a handle layer. A partial buried insulator overlies the handle layer and underlies the active layer, terminates at a buried insulator termination point, and includes an electrically insulating material. A substrate extension is adjacent to the partial buried insulator, where the substrate extension overlies the handle layer and underlies the active layer, and where the substrate extension directly contacts the partial buried insulator at the buried insulator termination point. The substrate extension includes a semiconductive material. A memory gate overlies the active layer.

Abstract: An apparatus for detecting an object capable of emitting light. The apparatus comprises a light detector comprising at least two optical sensors capable of determining the intensity of the light; and a computer processing output signal generated by the optical sensors and comparing a result of the processing with a known result corresponding to a known type to determine whether the object belongs to the known type.

Abstract: Semiconductor devices and methods of forming the same include forming a liner over one or more channel fins on a substrate. An etch is performed down into the substrate using the one or more channel fins and the liner as a mask to form a substrate fin underneath each of the one or more channel fins. An area around the one or more channel fins and substrate fins is filled with a flowable dielectric. The flowable dielectric is annealed to solidify the flowable dielectric. The anneal oxidizes at least a portion of sidewalls of each substrate fin, such that each substrate fin is narrower in the oxidized portion than in a portion covered by the liner.

Abstract: A mixed ionic electron conductor (MIEC)-based memory cell access device is provided. The MIEC-based memory cell access device includes a MIEC material portion located between a bottom electrode and a top electrode. A contact area between the MIEC material portion and the bottom electrode is substantially the same as a contact area between the MIEC material portion and the top electrode.

Abstract: Some embodiments of the present disclosure relate to a deep trench isolation structure. This deep trench isolation structure is formed on a semiconductor substrate having an upper semiconductor surface. A deep trench, which has a deep trench width as measured between opposing deep trench sidewalls, extends into the semiconductor substrate beneath the upper semiconductor surface. A fill material is formed in the deep trench, and a dielectric liner is disposed on a lower surface and sidewalls of the deep trench to separate the fill material from the semiconductor substrate. A shallow trench region has sidewalls that extend upwardly from the sidewalls of the deep trench to the upper semiconductor surface. The shallow trench region has a shallow trench width that is greater than the deep trench width. A dielectric material fills the shallow trench region and extends over top of the conductive material in the deep trench.

Abstract: According to one embodiment, a semiconductor device includes a first interconnection, a first semiconductor region, a stacked body, a columnar portion, first insulators, and arrays. The first interconnection is provided on a substrate via a first insulating film interposed. The first semiconductor region is provided on the first interconnection via a second insulating film. The stacked body is provided on the first semiconductor region. The columnar portion is provided in the stacked body. The first insulators are provided in the stacked body. The first insulators extend in the stacking direction and a first direction crossing the stacking direction. The arrays are provided in the first semiconductor region. The arrays each include second semiconductor regions. The second semiconductor regions are separated from each other. The second semiconductor regions are provided under the first insulators. The second semiconductor regions are electrically connected to the first interconnection.

Abstract: Semiconductor devices are provided including a first active fin extending in a first direction and a second active fin spaced apart from the first active fin in a second direction perpendicular to the first direction, the second active fin extending in the first direction, the second active fin having a longer side shorter than a length of a longer side of the first active fin. A first dummy gate extends in the second direction overlapping a first end of each of the first and second active fins. A first metal gate extends in the second direction intersecting the first active fin and overlapping a second end of the second active fin. A first insulating gate extends in the second direction intersecting the first active fin. The first insulating gate extends into the first active fin.

Abstract: An optoelectronic device includes a semiconductor substrate, having front and back sides and having at least one cavity extending from the back side through the semiconductor substrate into proximity with the front side. At least one optoelectronic emitter is formed on the front side of the semiconductor substrate in proximity with the at least one cavity. A heat-conducting material at least partially fills the at least one cavity and is configured to serve as a heat sink for the at least one optoelectronic emitter.

Abstract: A semiconductor substrate is a provided and an insulating layer is formed thereon. A cavity structure is formed above the insulating layer, including a lateral growth channel and a fin seed structure arranged in the lateral growth channel. The fin seed structure provides a seed surface for growing a fin structure. One or more first semiconductor structures of a first semiconductor material and one or more second semiconductor structures of a second, different, semiconductor material are grown sequentially in the growth channel from the seed surface in an alternating way. The first semiconductor structures provide a seed surface for the second semiconductor structures and the second semiconductor structures provide a seed surface for the first semiconductor structures. The second semiconductor structures are selectively etched, thereby forming the fin structure comprising a plurality of parallel fins of the first semiconductor structures. Corresponding semiconductor structures are also included.

Abstract: In a method for forming a device, a (110) silicon substrate is etched to form first trenches in the (110) silicon substrate, wherein remaining portions of the (110) silicon substrate between the first trenches form silicon strips. The sidewalls of the silicon strips have (111) surface orientations. The first trenches are filled with a dielectric material to from Shallow Trench Isolation (STI) regions. The silicon strips are removed to form second trenches between the STI regions. An epitaxy is performed to grow semiconductor strips in the second trenches. Top portions of the STI regions are recessed, and the top portions of the semiconductor strips between removed top portions of the STI regions form semiconductor fins.

Abstract: III-nitride materials are generally described herein, including material structures comprising III-nitride material regions and silicon-containing substrates. Certain embodiments are related to gallium nitride materials and material structures comprising gallium nitride material regions and silicon-containing substrates.

Abstract: A semiconductor device that includes a first plurality of fin structures in a first device region and a second plurality of fin structures in a second device region. The first plurality of fin structures includes adjacent fin structures separated by a lesser pitch than the adjacent fin structures in the second plurality of fin structures. At least one layer of dielectric material between adjacent fin structures, wherein a portion of the first plurality of fin structures extending above the at least one layer of dielectric material in the first device region is substantially equal to the portion of the second plurality of fin structures extending above the at least one layer of dielectric material in the second device region. Source and drain regions are present on opposing sides of a gate structure that is present on the fin structures.

Abstract: Silicon-on-insulator integrated circuits including body contact structures and methods for fabricating the same are disclosed. A method for fabricating a silicon-on-insulator integrated circuit includes filling a plurality of first and second shallow isolation trenches with an insulating material to form plurality of first and second shallow trench isolation (STI) structures, the plurality of second shallow isolation trenches having doped regions therebeneath, and forming a gate structure over the semiconductor layer that includes a first portion disposed over and parallel to at least two of the plurality of second STI structures and a second portion disposed in between the at least two of the plurality of second STI structures. The method further includes forming contact plugs to a body contact or gate region of the semiconductor layer.

Abstract: A semiconductor device and a manufacturing method thereof are disclosed. The semiconductor device includes a silicon substrate, a spacer, a doped region, and a deep trench isolation (DTI). The silicon substrate has a deep trench. The spacer is formed on an upper portion of the sidewall of the deep trench. The doped region is formed on a lower portion of the sidewall of the deep trench. The deep trench isolation is formed in the deep trench.

Abstract: A method for forming fine patterns includes patterning a hard mask layer on an etch target layer to form sacrificial pillars and a first opening disposed between the sacrificial pillars and exposing the etch target layer, forming a block copolymer layer on the etch target layer exposed through the first opening, phase-separating the block copolymer layer to form first block patterns spaced apart from the sacrificial pillars and a second block pattern, forming first holes by etching the etch target layer exposed by removing the first block patterns, and forming second holes in the etch target layer exposed by removing the sacrificial pillars, the second holes being different from the first holes.

Abstract: An example method includes providing a layer stack in a trench defined by adjacent STI structures and recessing the STI structures adjacent to the layer stack to thereby expose an upper portion of the layer stack, the upper portion comprising at least a channel portion. The method further includes providing one or more protection layers on the upper portion of the layer stack and then further recessing the STI structures selectively to the protection layers and the layer stack, to thereby expose a central portion of the layer stack. And the method includes removing the central portion of the layer stack, resulting in a freestanding upper part and a lower part of the layer stack being physically separated from each other.

Abstract: A semiconductor device includes: a substrate, a fin-shaped structure on the substrate, and a dummy fin-shaped structure on the substrate and adjacent to the fin-shaped structure. Preferably, the fin-shaped structure includes a gate structure thereon and a first epitaxial layer adjacent to two sides of the gate structure, and the dummy fin-shaped structure includes a second epitaxial layer thereon. A contact plug is disposed on the first epitaxial layer and the second epitaxial layer. In addition, the dummy fin-shaped structure includes a curve, in which the curve is omega shaped.

Abstract: A method for fabricating semiconductor device is disclosed. First, a substrate, and a sacrificial mandrel is formed on the substrate, in which the sacrificial mandrel includes a first side and a second side with the indentation. Next, a spacer is formed adjacent to the first side and the second side of the sacrificial mandrel, the sacrificial mandrel is removed, and the spacer is used to remove part of the substrate for forming a fin-shaped structure and a dummy fin-shaped structure.

Abstract: A manufacturing method of a graphene modulated high-k oxide and metal gate Ge-based MOS device, which comprises the following steps: 1) introducing a graphene thin film on a Ge-based substrate; 2) conducting fluorination treatment to the graphene thin film to form fluorinated graphene; 3) activating the surface of the fluorinated graphene by adopting ozone plasmas, and then forming a high-k gate dielectric on the surface of the fluorinated graphene through an atomic layer deposition technology; and 4) forming a metal electrode on the surface of the high-k gate dielectric. Since the present invention utilizes the graphene as a passivation layer to inhibit the formation of unstable oxide GeOx on the surface of the Ge-based substrate and to stop mutual diffusion between the gate dielectric and the Ge-based substrate, the interface property between Ge and the high-k gate dielectric layer is improved.

Abstract: An integrated circuit, including: a UTBOX layer; a first cell, including: FDSOI transistors; a first STI separating the transistors; a first ground plane located beneath one of the transistors and beneath the UTBOX layer; a first well; a second cell, including: FDSOI transistors; a second STI separating the transistors; a second ground plane located beneath one of the transistors and beneath the UTBOX layer; a second well; a third STI separating the cells, reaching the bottom of the first and second wells; a deep well extending continuously beneath the first and second wells, having a portion beneath the third STI whose doping density is at least 50% higher than the doping density of the deep well beneath the first and second STIs.

Abstract: The present invention provides a semiconductor structure, including a substrate, a shallow trench isolation (STI) disposed in the substrate, a plurality of first fin structures disposed in the substrate, where each first fin structure and the substrate have same material, and a plurality of second fin structures disposed in the STI, where each second fin structure and the STI have same material.

Abstract: A semiconductor FET device includes a buffer structure and a fin structure. The buffer structure has a fin shape, is disposed over a substrate and extends along a first direction. The fin structure includes a channel region of the FET device, is disposed on the buffer structure and extends along the first direction. The width of the buffer structure along a second direction perpendicular to the first direction is greater than the width of the fin structure along the second direction measured at an interface between the buffer structure and the fin structure.

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 integrated circuit, including: a first cell, including: FDSOI transistors; a UTBOX layer lying beneath the transistors; a first well lying beneath the insulator layer and beneath the transistors, the first well having a first type of doping; a first ground plane having a second type of doping, located beneath one of the transistors and between the insulator layer and the first well; a first STI separating the transistors and crossing the insulator layer; a first conductive element forming an electrical connection between the first well and the first ground plane, located under the first STI; a second cell including a second well; a second STI separating the cells, crossing the insulator layer and reaching the bottom of the first and second wells.

Abstract: A method for manufacturing a semiconductor device includes forming a fin structure over a substrate. An isolation insulating layer is formed so that an upper part of the fin structure protrudes from the isolation insulating layer. A gate structure is formed over a part of the fin structure. Recesses are formed in the isolation insulating layer at both sides of the fin structure. A recess is formed in a portion of the fin structure which is not covered by the gate structure. The recess in the fin structure and the recesses in the isolation insulating layer are formed such that a depth D1 of the recess in the fin structure and a depth D2 of the recesses in the isolation insulating layer measured from an uppermost surface of the isolation insulating layer satisfy 0?D1?D2 (but D1 and D2 are not zero at the same time).

Abstract: A method can include performing an etching process to define a fin trench having a first depth, the first depth being less that a target height of fin. A method can also include forming a layer to protect sidewalls defining the fin trench. A method can also include performing a second etching process to increase a depth of fin trench.

Abstract: An electrostatic discharge protection circuit is disclosed. A method of manufacturing a semiconductor structure includes forming a semiconductor controlled rectifier including a first plurality of fingers between an n-well body contact and an anode in an n-well, and a second plurality of fingers between a p-well body contact and a cathode in a p-well.

Abstract: A semiconductor device includes an oxide film structure having different thicknesses depending on where the oxide film structure is formed. In the semiconductor device, a wall oxide film is formed to have different thicknesses depending on locations of sidewalls of an active region. The semiconductor device includes an active region, a first wall oxide film disposed over a first sidewall of the active region that extends along a first direction of the active region, the first wall oxide film having a first thickness, and a second wall oxide film disposed over a second sidewall of the active region that extends along a second direction of the active region, a second wall oxide film having a second thickness that is different from the first thickness.

Abstract: Methods for creating self-aligned FINFET SDBs for minimum gate junction pitch and epitaxy formation. Embodiments include forming separated openings in a hard mask on upper surfaces of Si fins; forming cavities in the fins, each of the cavities having a concave shape and a width extending under the hard mask on each side of the cavity; forming trenches in the fins, the trenches having an upper width substantially equal to a width of the openings and less than the width of a cavity; removing the hard mask; filling the trenches and the cavities with oxide, forming STI regions; forming an oxide mask layer on the upper surfaces of the fins and the STI regions; removing upper portions of the oxide in sections between the STI regions; and removing remaining portions of the oxide mask revealing the fins and upper surfaces of the STI regions.

Abstract: An RF communications device may include a circuit board having a dielectric layer and conductive traces, one of the conductive traces defining a transmission line. The RF communications device may also include an RF transmitter carried by the circuit board and coupled to the transmission line, and RF switching circuits, each RF switching circuit including a substrate having a tapered proximal end coupled to the transmission line, and a distal end extending outwardly on the convex side of the transmission line. Each RF switching circuit may include a series diode, and a shunt diode coupled to the series diode, the series diode extending from the tapered proximal end and across an interior of the substrate.

Abstract: A method for forming a semiconductor device comprises forming an insulator layer on a semiconductor substrate, removing portions of the insulator layer to form a first cavity and a second cavity, the first cavity exposing a first portion of the semiconductor substrate an the second cavity exposing a second portion of the semiconductor substrate, growing a first semiconductor material in the first cavity and the second cavity. Growing a second semiconductor material on the first semiconductor material in the first cavity and the second cavity, growing a third semiconductor material on the second semiconductor material in the first cavity and the second cavity. Forming a mask over the third semiconductor material in the first cavity, removing the third semiconductor material from the second cavity to expose the second semiconductor material in the second cavity, and growing a fourth semiconductor material on the second semiconductor material in the second cavity.

Abstract: A method for fabricating a fin field effect transistor (FinFET) is provided. The method includes steps as follows. A gate stack is formed over a substrate having a semiconductor fin. Recesses are formed in the semiconductor fin beside the gate stack. A pre-clean process is performed to remove native oxides on surfaces of the recesses. After the pre-clean process, a selectivity proximity push process is performed using a fluorine-containing gas and a first hydrogen gas to the recesses. Strained layers are formed in the recesses.

Abstract: One method disclosed includes, among other things, forming a structure comprised of an island of a first insulating material positioned between the gate structures above the source/drain region and under a masking layer feature of a patterned masking layer, forming a liner layer that contacts the island of insulating material and the masking layer feature, selectively removing the masking layer feature to thereby form an initial opening that is defined by the liner layer, performing at least one isotropic etching process through the initial opening to remove the island of first insulating material and thereby define a contact opening that exposes the source/drain region, and forming a conductive contact structure in the contact opening that is conductively coupled to the source/drain region.

Abstract: FinFET devices and methods of making the same. A structure includes: a substrate with a buried insulator, a plurality of fins over a recessed buried insulator, and a nitride material filing recessed spaces between the plurality of fins, wherein the plurality of fins remain uncovered by the nitride, and wherein the nitride material does not contact the bottom of the plurality of fins.

Abstract: Disclosed are semiconductor structures comprising a field effect transistor (FET) having a low-resistance source/drain contact and, optionally, low gate-to-source/drain contact capacitance. The structures comprise a semiconductor body and, contained therein, first and second source/drain regions and a channel region. A first gate is adjacent to the semiconductor body at the channel region and a second, non-functioning, gate is adjacent to the semiconductor body such that the second source/drain region is between the first and second gates. First and second source/drain contacts are on the first and source/drain regions, respectively. The second source/drain contact is wider than the first and, thus, has a lower resistance. Additionally, spacing of the first and second source/drain contacts relative to the first gate can be such that the first gate-to-second source/drain contact capacitance is equal to or less than the first gate-to-first source/drain contact capacitance.

Abstract: A trench-isolated RESURF diode structure (100) is provided which includes a substrate (150) in which is formed anode (130, 132) and cathode (131) contact regions separated from one another by a shallow trench isolation region (114, 115), along with a buried cathode extension region (104) formed under a RESURF anode extension region (106, 107) such that the cathode extension region (104) extends beyond the cathode contact (131) to be sandwiched between upper and lower regions (103, 106, 107) of opposite conductivity type.

Abstract: A semiconductor structure is provided that includes a semiconductor on insulator (SOI) substrate comprising a bottom semiconductor layer, an epitaxial semiconductor layer present on the bottom semiconductor layer, a buried insulator layer present on the epitaxial semiconductor layer, and a top semiconductor layer present on the buried insulator layer. A deep trench moat (DTMOAT) is disposed in the SOI substrate and has a bottom surface contacting a dopant region of the bottom semiconductor layer. A moat contact electrically connecting the DTMOAT to the epitaxial semiconductor layer of the SOI substrate. Charges accumulated in the DTMOAT can be discharged through the heavily doped epitaxial semiconductor layer to ground, thus preventing the DTMOAT failure caused by the process-induced charge accumulation.

Abstract: An SOI substrate, a semiconductor device, and a method of backgate work function tuning. The substrate and the device have a plurality of metal backgate regions wherein at least two regions have different work functions. The method includes forming a mask on a substrate and implanting a metal backgate interposed between a buried oxide and bulk regions of the substrate thereby producing at least two metal backgate regions having different doses of impurity and different work functions. The work function regions can be aligned such that each transistor has different threshold voltage. When a top gate electrode serves as the mask, a metal backgate with a first work function under the channel region and a second work function under the source/drain regions is formed. The implant can be tilted to shift the work function regions relative to the mask.

Abstract: A plurality of first miniature elements of an overlay mark is formed in a first layer. A plurality of second miniature elements of the overlay mark is formed in a second layer different from the first layer. A plurality of dummy features is formed around the overlay mark. The dummy features are formed such that they each have a dimension below a resolution of an alignment detection tool configured to optically scan the overlay mark in an alignment process.

Abstract: Package structures are provided for integrally packaging antennas with semiconductor RFIC (radio frequency integrated circuit) chips to form compact integrated radio/wireless communications systems that operate in the millimeter-wave and terahertz frequency ranges. For example, a package structure includes an RFIC chip, and an antenna package bonded to the RFIC chip. The antenna package includes a glass substrate, at least one planar antenna element formed on a first surface of the glass substrate, a ground plane formed on a second surface of the glass substrate, opposite the first surface, and an antenna feed line formed through the glass substrate and connected to the at least one planar antenna element. The antenna package is bonded to a surface of the RFIC chip using a layer of adhesive material.

Abstract: A technique relates to manufacturing a finFET device. A plurality of first and second semiconductor fins are formed on a substrate. Gate stacks are formed on the substrate, each including a gate, a hard mask and an oxide layer. A dielectric spacer layer is deposited. A sacrificial fill material is deposited on the finFET device and planarized. A second hard mask is deposited, a trench area is patterned in the hard mask parallel to the first and second semiconductor fins, and the sacrificial fill material is anisotropically etched to create a trench. A dielectric wall is formed in the trench and the second hard mask and sacrificial fill material are removed.

Abstract: The present disclosure provides an apparatus and method for fabricating a semiconductor gate. The apparatus includes, a substrate having an active region and a dielectric region that forms an interface with the active region; a gate electrode located above a portion of the active region and a portion of the dielectric region; and a dielectric material disposed within the gate electrode, the dielectric material being disposed near the interface between the active region and the dielectric region. The method includes, providing a substrate having an active region and a dielectric region that forms an interface with the active region; forming a gate electrode over the substrate, the gate electrode having an opening near a region of the gate electrode that is above the interface; and filling the opening with a dielectric material.

Abstract: A method of forming a pattern including applying a resist composition to a substrate to form a resist film, and then subjecting the resist film to exposure and development, thereby forming a first pattern containing a resist film; forming a SiO2 film on the surface of the first pattern and the substrate; subjecting the SiO2 to etching such that the SiO2 film remains only on a side wall portion of the first pattern; and removing the first pattern, thereby forming a second pattern containing the SiO2 film. The resist composition contains a base component that exhibits changed solubility in a developing solution under action of an acid, and an acid generator component that generates acid upon exposure, the base component containing a resin component containing a structural unit having an acid decomposable group which exhibits increased polarity by the action of acid and has no polycyclic group.

Abstract: A package includes an inorganic dielectric layer, and a capacitor. The capacitor includes a bottom electrode having a top surface in contact with a top surface of the inorganic dielectric layer, an insulator over the bottom electrode, and a top electrode over the insulator. The package further includes a polymer layer covering the capacitor, with a portion of the polymer layer being coplanar with the capacitor and encircling the capacitor. The polymer contacts the top surface of the inorganic dielectric layer.

Abstract: In one embodiment, a vertical insulated-gate field effect transistor includes a feature embedded within a control electrode. The feature is placed within the control electrode to induce stress within predetermined regions of the transistor.

Abstract: A semiconductor device includes a semiconductor substrate having a first surface, a through silicon via (TSV) that is formed so that at least a part thereof penetrates through the semiconductor substrate, and an insulation ring. The insulation ring is formed so as to penetrate through the semiconductor substrate and so as to surround the TSV. The insulation ring includes a tapered portion and a vertical portion. The tapered portion has a sectional area which is gradually decreased from the first surface toward a thickness direction of the semiconductor substrate. The vertical portion has a constant sectional area smaller than the tapered portion.