Abstract: A semiconductor device and a method for fabricating the same are provided to prevent a floating body effect and reduce coupling capacitance between buried bit lines. The semiconductor device comprises a first pillar disposed over a semiconductor substrate and including a vertical channel region, a bit line located in the lower portion of the vertical channel region inside the first pillar and a semiconductor layer extended from the semiconductor substrate to one sidewall of the first pillar.

Abstract: A semiconductor device includes conductive features within a gate electrode level region that are each fabricated from a respective originating rectangular-shaped layout feature having a centerline aligned parallel to a first direction. The conductive features form gate electrodes of first and second PMOS transistor devices, and first and second NMOS transistor devices. The gate electrodes of the first PMOS and first NMOS transistor devices extend along a first gate electrode track. The gate electrodes of the second PMOS and second NMOS transistor devices extend along a second gate electrode track. A first set of interconnected conductors electrically connect the gate electrodes of the first PMOS and second NMOS transistor devices. A second set of interconnected conductors electrically connect the gate electrodes of the second PMOS and first NMOS transistor devices. The first and second sets of interconnected conductors traverse across each other within different levels of the semiconductor device.

Abstract: A unit pixel array of an image sensor includes a semiconductor substrate having a plurality of photodiodes, an interlayer insulation layer on a front-side of the semiconductor substrate, and a plurality of micro lenses on a back-side of the semiconductor substrate. The unit pixel array of the image sensor further includes a wavelength adjustment film portion between each of the micro lenses and the back-side of the semiconductor substrate such that a plurality of wavelength adjustment film portions correspond with the plurality of micro lenses.

Abstract: A semiconductor device with substrate-side exposed device-side electrode (SEDE) is disclosed. The semiconductor device has semiconductor substrate (SCS) with device-side, substrate-side and semiconductor device region (SDR) at device-side. Device-side electrodes (DSE) are formed for device operation. A through substrate trench (TST) is extended through SCS, reaching a DSE turning it into an SEDE. The SEDE can be interconnected via conductive interconnector through TST. A substrate-side electrode (SSE) and a windowed substrate-side passivation (SSPV) atop SSE can be included. The SSPV defines an area of SSE for spreading solder material during device packaging. A device-side passivation (DSPV) beneath thus covering the device-side of SEDE can be included. A DSE can also include an extended support ledge, stacked below an SEDE, for structurally supporting it during post-wafer processing packaging.

Abstract: A gate stack is formed on a silicon layer that is above a buried oxide layer. The gate stack comprises a high-k oxide layer on the silicon layer and a metal gate on the high-k oxide layer. A first nitride layer is formed on the silicon layer and the gate stack. An oxide layer is formed on the first nitride layer. A second nitride layer is formed on the oxide layer. The first nitride layer and the oxide layer are etched so as to form a nitride liner and an oxide liner adjacent to the gate stack. The second nitride layer is etched so as to form a first nitride spacer adjacent to the oxide liner. A faceted raised source/drain region is epitaxially formed adjacent to the nitride liner, the oxide liner, and first nitride spacer. Ions are implanted into the faceted raised source/drain region using the first nitride spacer.

Abstract: A semiconductor device includes a cross-coupled transistor configuration formed by first and second PMOS transistors defined over first and second p-type diffusion regions, and by first and second NMOS transistors defined over first and second n-type diffusion regions, with each diffusion region electrically connected to a common node. Gate electrodes of the PMOS and NMOS transistors are formed by conductive features which extend in only a first parallel direction. The first and second p-type diffusion regions are formed in a spaced apart manner, such that no single line of extent that extends perpendicular to the first parallel direction intersects both the first and second p-type diffusion regions. The first and second n-type diffusion regions are formed in a spaced apart manner, such that no single line of extent that extends perpendicular to the first parallel direction intersects both the first and second n-type diffusion regions.

Abstract: A first gate level feature forms gate electrodes of a first transistor of a first transistor type and a first transistor of a second transistor type. A second gate level feature forms a gate electrode of a second transistor of the first transistor type. A third gate level feature forms a gate electrode of a second transistor of the second transistor type. The gate electrodes of the second transistors of the first and second transistor types are positioned on opposite sides of a gate electrode track along which the gate electrodes of the first transistors of the first and second transistor types are positioned. The gate electrodes of the second transistors of the first and second transistor types are electrically connected to each other through an electrical connection that includes respective gate contacts and a conductive interconnect structure.

Abstract: Image sensor, fabricating method thereof, and device comprising the image sensor are provided, which comprises a substrate in which a photoelectric transformation device is formed, an interconnection structure formed on the substrate and including multiple intermetal dielectric layers and multiple metal interconnections placed in the multiple intermetal dielectric layers, the interconnection structure defining a cavity aligned corresponding to the photoelectric transformation device, a moisture absorption barrier layer conformally formed on a top of the interconnection structure and in the cavity; and a light guide unit formed on the moisture absorption barrier layer and including light transmittance material filling the cavity, wherein the moisture absorption barrier layer is formed with a uniform thickness on both sides and a bottom of the cavity and on a top surface of the multiple intermetal dielectric layer.

Abstract: A first linear-shaped conductive structure (LCS) forms a gate electrode (GE) of a first transistor of a first transistor type. A second LCS forms a GE of a first transistor of a second transistor type. A third LCS forms a GE of a second transistor of the first transistor type. A fourth LCS forms a GE of a second transistor of the second transistor type. Each of the first, second, third, and fourth LCS's has a respective electrical connection area. The electrical connection areas of the first and third LCS's are offset from each other. The GE of the first transistor of the first transistor type is electrically connected to the GE of the second transistor of the second transistor type. The GE of the second transistor of the first transistor type is electrically connected to the GE of the first transistor of the second transistor type.

Abstract: A first gate level feature forms gate electrodes of a first transistor of a first transistor type and a first transistor of a second transistor type. A second gate level feature forms a gate electrode of a second transistor of the first transistor type. A third gate level feature forms a gate electrode of a second transistor of the second transistor type. The gate electrodes of the second transistors of the first and second transistor types are positioned on opposite sides of a gate electrode track along which the gate electrodes of the first transistors of the first and second transistor types are positioned. The gate electrodes of the second transistors of the first and second transistor types are electrically connected to each other through an electrical connection that includes two conductive contacting structures at a location not over an inner non-diffusion region.

Abstract: A method of forming a semiconductor device includes defining a first type region and a second type region in a substrate, t separated by one or more inter-well STI structures; etching and filling, in at least one of the first type region and the second type region, one or more intra-well STI structures for isolating semiconductor devices formed within a same polarity well, wherein the one or more inter-well STI structures are formed at a substantially same depth with respect to the one or more intra-well STI structures; implanting, a main well region, wherein a bottom of the main well region is disposed above a bottom of the one or more inter-well and intra-well STI features; and implanting, one or more deep well regions that couple main well regions, wherein the one or more deep well regions are spaced away from the one or more inter-well STI structures.

Abstract: A first gate level feature forms gate electrodes of a first transistor of a first transistor type and a first transistor of a second transistor type. A second gate level feature forms a gate electrode of a second transistor of the first transistor type. A third gate level feature forms a gate electrode of a second transistor of the second transistor type. The gate electrodes of the second transistors of the first and second transistor types are electrically connected to each other. The gate electrodes of the second transistors of the first and second transistor types are positioned on opposite sides of a gate electrode track along which the gate electrodes of the first transistors of the first and second transistor types are positioned.

Abstract: Gate-all-around integrated circuit devices include first and second source/drain regions on an active area of an integrated circuit substrate. The first and second source/drain regions form p-n rectifying junctions with the active area. A channel region extends between the first and second source/drain regions. An insulated gate electrode surrounds the channel region.

Abstract: A light emitting device includes: a light emitting chip arranged on a substrate; a resin lens which covers the light emitting chip and focuses irradiation light from the light emitting chip; a mask which covers a region of an upper layer surface of the substrate, other than the resin lens; and a low surface tension film formed on a region of the upper layer surface of the substrate, other than in the proximity of the light emitting chip.

Abstract: Transistors having sulfur-doped zinc oxynitride channel layers, and methods of manufacturing the same, include a ZnON channel layer with sulfur content ratio with respect to a zinc content of from about 0.1 at % to about 1.2 at %, a source electrode and a drain electrode respectively formed on a first region and a second region of the channel layer, a gate electrode corresponding to the channel layer, and a gate insulation layer between the channel layer and the gate electrode.

Abstract: A semiconductor package includes a base substrate, a semiconductor chip mounted on the base substrate and including bonding pads, first and second connection terminals disposed adjacent to the semiconductor chip on the base substrate and electrically connected to the bonding pads, a first ball land disposed on the base substrate and electrically connected to the first connection terminal, a second ball land spaced apart from the connection terminals, the first ball land disposed between the second ball land and at least one of the first and second connection terminals, a first insulating layer covering the first ball land but exposing at least a part of the second ball land, and a first conductive wire extending onto the first insulating layer and connecting the second connection terminal to the second ball land.

Abstract: A high linearity bandgap engineered transistor device is provided. In one example configuration, the device generally includes a substrate and an oxide layer formed on the substrate. The device further includes a wide-bandgap body material formed between a portion of the oxide layer and a gate dielectric layer. The wide-bandgap body material has an energy bandgap of 1.35 eV or higher and is lattice matched to the substrate. The device further includes a source-drain material formed on the oxide layer adjacent to the wide-bandgap body material so as to define a hetero-structure interface where the source-drain material contacts the wide-bandgap body material. The wide-bandgap body material is also lattice matched to the source-drain material. The device further includes a gate material formed over the gate dielectric layer. Other features and variations will be apparent in light of this disclosure.

Abstract: A semiconductor wafer contains a plurality of die with contact pads disposed on a first surface of each die. Metal vias are formed in trenches in the saw street guides and are surrounded by organic material. Traces connect the contact pads and metal vias. The metal vias can be half-circle vias or full-circle vias. Metal vias are also formed through the contact pads on the active area of the die. Redistribution layers (RDL) are formed on a second surface of the die opposite the first surface. Repassivation layers are formed between the RDL for electrical isolation. The die are stackable and can be placed in a semiconductor package with other die. The vias through the saw streets and vias through the active area of the die, as well as the RDL, provide electrical interconnect to the adjacent die.

Abstract: One embodiment discloses an apparatus integrating a microelectromechanical system device with a circuit chip which comprises a circuit chip, a microelectromechanical system device, a sealing ring, and a lid. The circuit chip comprises a substrate and a plurality of metal bonding areas. The substrate has an active surface with electrical circuit area, and the metal bonding areas are disposed on the active surface and electrically connected to the electrical circuits. The microelectromechanical system device comprises a plurality of bases and at least one sensing element. The bases are connected to at least one of the metal bonding areas. The at least one sensing element is elastically connected to the bases. The sealing ring surrounds the bases, and is connected to at least one of the metal bonding areas. The lid is opposite to the active surface of the circuit chip, and is connected to the sealing ring to have a hermetic chamber which seals the sensing element and the active surface of the circuit chip.

Abstract: Structures and manufacturing processes of an ACF array using a non-random array of microcavities of predetermined configuration, shape and dimension. The manufacturing process includes fluidic filling of conductive particles onto a substrate or carrier web comprising a predetermined array of microcavities, or selective metallization of the array followed by filling the array with a filler material and a second selective metallization on the filled microcavity array. The thus prepared filled conductive microcavity array is then over-coated or laminated with an adhesive film. Cavities in the array, and particles filling the cavities, can have a unimodal, bimodal, or multimodal distribution.