Abstract: Systems and methods for forming films on the surface of a substrate are described. The systems possess aerosol generators which form droplets from a liquid solution made from a solvent and a deposition precursor. A carrier gas may be flowed through the liquid solution and push the droplets toward a substrate placed in a substrate processing region. The droplets pass into the substrate processing region and chemically react with the substrate to form films. The temperature of the substrate may be maintained below the boiling temperature of the solvent during film formation. The solvent imparts a flowability to the forming film and enable the depositing film to flow along the surface of a patterned substrate during formation prior to solidifying. The flowable film results in bottom-up gapfill inside narrow high-aspect ratio gaps in the patterned substrate.

Abstract: One aspect of the invention relates to a method for producing a chip assemblage. Two or more chip assemblies are produced in each case by cohesively and electrically conductively connecting an electrically conductive first compensation lamina to a first main electrode of a semiconductor chip. A control electrode interconnection structure is arranged in a free space between the chip assemblies. Electrically conductive connections are produced between the control electrode interconnection structure and control electrodes of the semiconductor chips of the individual chip assemblies. The chip assemblies are cohesively connected by means of a dielectric embedding compound.

Abstract: Provided herein is a semiconductor device. The semiconductor device may include conductive layers each including a line, and a pad which is coupled with the line and has a thickness greater than that of the line, the conductive layers being stacked such that the pads are exposed; insulating layers interposed between the conductive layers; first spacers each of which is interposed between the pad of the corresponding upper conductive layer and the pad of the corresponding low conductive layer; and second spacers covering the respective first spacers.

Abstract: A solid state image sensor includes a semiconductor substrate where photoelectric conversion regions for converting light into charges are arranged per pixel planarly arranged; an organic photoelectric conversion film laminated at a light irradiated side of the semiconductor substrate via an insulation film and formed at the regions where the pixels are formed; a lower electrode formed at and in contact with the organic photoelectric conversion film at a semiconductor substrate side; a first upper electrode laminated at a light irradiated side of the organic photoelectric conversion film and formed such that ends of the first upper electrode are substantially conform with ends of the organic photoelectric conversion film when the solid state image sensor is planarly viewed; and a film stress suppressor for suppressing an effect of a film stress on the organic photoelectric conversion film, the film stress being generated on the first upper electrode.

Abstract: A structure and method for forming a tungsten region for a replacement metal gate (RMG). The method for forming the tungsten region may include, among other things, forming a first tungsten region i.e., tungsten seed layer, on a liner in a trench of a dielectric layer; removing a portion of the liner and the tungsten seed layer to expose an uppermost surface of a work function metal (WFM) layer wherein an uppermost surface of the liner and tungsten seed layer is positioned below an uppermost surface of the dielectric layer; and forming a second tungsten region from the tungsten seed layer. The tungsten region may be formed to contact the uppermost surface liner, the uppermost surface of WFM layer, and/or the sidewalls of the trench. The tungsten region may include a single crystallographic orientation. The tungsten region may also include an uppermost surface with a substantially arcuate cross-sectional geometry.

Abstract: Described are methods for controlling the doping of metal nitride films such as TaN, TiN and MnN. The temperature during deposition of the metal nitride film may be controlled to provide a film density that permits a desired amount of doping. Dopants may include Ru, Cu, Co, Mn, Mo, Al, Mg, Cr, Nb, Ta, Ti and V. The metal nitride film may optionally be exposed to plasma treatment after doping.

Abstract: A method of manufacturing a semiconductor device includes stacking a molding layer and a preliminary support layer on a substrate, forming a support layer having a plurality of openings by removing at least a portion of the preliminary support layer, forming a sacrificial layer by filling the plurality of openings with a different material from a material of the molding layer and from a material of the preliminary support layer, forming a plurality of vertical holes through the support layer and through the molding layer, forming a lower electrode within the plurality of vertical holes, and removing the sacrificial layer and the molding layer.

Abstract: Methods for fabricating integrated circuits are provided. In one example, a method includes depositing an ILD layer overlying a SOI substrate including a device structure and an isolation structure. The device structure is disposed on a semiconductor layer of the SOI substrate and includes a metal silicide region and the isolation structure extends through the semiconductor layer to a buried insulator layer of the SOI substrate. A patterned mask is used for etching through the ILD layer and forming a device contact opening that exposes the metal silicide region and a substrate contact opening that exposes the isolation structure. A device contact is formed in the device contact opening. The isolation structure and the buried insulator layer are etched through to extend the substrate contact opening to a support substrate of the SOI substrate. A substrate contact is formed in the substrate contact opening.

Abstract: A light emitting device includes a wavelength conversion layer, at least one light emitting unit and a reflective protecting element. The wavelength conversion layer has an upper surface and a lower surface opposite to each other. The light emitting unit has two electrode pads located on the same side of the light emitting unit. The light emitting unit is disposed on the upper surface of the wavelength conversion layer and exposes the two electrode pads. The reflective protecting element encapsulates at least a portion of the light emitting unit and a portion of the wavelength conversion layer, and exposes the two electrode pads of the light emitting unit.

Abstract: Methods of singulating semiconductor die. Specific implementations may include: providing a semiconductor wafer including a plurality of die located on a first side of the semiconductor wafer where the plurality of die include a desired thickness. The method may include etching a plurality of trenches into the semiconductor wafer from the first side of the semiconductor wafer where the plurality of trenches is located adjacent to a perimeter of the plurality of die. A depth of the plurality of trenches may be greater than the desired thickness of the plurality of die. The method may also include mounting the first side of the semiconductor wafer to a tape, thinning a second side of the semiconductor wafer, exposing the plurality of trenches while thinning the second side, and singulating the plurality of die through exposing the plurality of trenches.

Abstract: A method of forming a memory device with memory cells over a planar substrate surface and FinFET logic devices over fin shaped substrate surface portions, including forming a protective layer over previously formed floating gates, erase gates, word line poly and source regions in a memory cell portion of the substrate, then forming fins into the surface of the substrate and forming logic gates along the fins in a logic portion of the substrate, then removing the protective layer and completing formation of word line gates from the word line poly and drain regions in the memory cell portion of the substrate.

Abstract: A semiconductor memory device according to an embodiment, includes a first stacked body, a second stacked body, an intermediate conductive layer, an intermediate insulating layer, a semiconductor pillar, a charge storage film, and an insulating film. The semiconductor pillar includes a first part, a second part, and a third part. The charge storage film includes a first charge storage portion and a second charge storage portion. The charge storage film includes at least one first element selected from the group consisting of nitrogen, hafnium, and aluminum. The insulating film provides in at least a portion between the intermediate conductive layer and the first part. The insulating film not includes the first element, or the insulating film has a concentration of the first element lower than a concentration of the first element of the charge storage film.

Abstract: A method is for forming a nitride or oxide film by plasma-assisted cyclic deposition, one cycle of which includes: feeding a first reactant, a second reactant, and a precursor to a reaction space where a substrate is placed, wherein the second reactant flows at a first flow ratio wherein a flow ratio is defined as a ratio of a flow rate of the second reactant to a total flow rate of gases flowing in the reaction space; and stopping feeding the precursor while continuously feeding the first and second reactants at a flow ratio which is gradually reduced from the first flow ratio to a second flow ratio while applying RF power to the reaction space to expose the substrate to a plasma. The second reactant is constituted by a hydrogen-containing compound or oxygen-containing compound.

Abstract: A semiconductor device includes a semiconductor substrate having a core device and an IO device. The core device includes a gate interface layer and a high-k dielectric layer on the gate interface layer. The IO device includes a gate interface layer and a high-k dielectric layer on the gate interface layer. The gate interface layer of the core device and the gate interface layer of the IO device each are doped with fluoride ions.

Abstract: An organic light-emitting display that includes a substrate comprising a pixel area, a thin film transistor arranged within the pixel area, a wiring electrically connected to the a thin film transistor, an insulating layer covering the thin film transistor and the wiring, a pixel electrode arranged over the insulating layer, a pixel-defining layer having an opening that exposes the pixel electrode, an opposite electrode facing the pixel electrode and an organic emission layer interposed between the pixel electrode and the opposite electrode, the insulating layer having a first region that is overlapped by the pixel electrode and a second region that is not overlapped by the pixel electrode, the second region being thicker than the first region to reduce parasitic capacitance between the opposite electrode and the wiring.

Abstract: A semiconductor structure includes a first dielectric layer, a first conductive via, a partial landing pad, a second dielectric layer, and a second conductive via. The first conductive via is disposed in the first dielectric layer. The partial landing pad is disposed on the first conductive via and the first dielectric layer, in which the partial landing pad has a top surface and a bottom surface, and the top surface of the partial landing pad has a width greater than or substantially equal to that of the bottom surface of the partial landing pad. The second dielectric layer is disposed on the partial landing pad. The second conductive via is disposed in the second dielectric layer and electrically connected to the partial landing pad.

Abstract: Disclosed is a method of manufacturing a semiconductor device, including: forming a multi-layered stack; forming a vertical hole in the stack; forming a plurality of material layers over a bottom and a sidewall of the vertical hole, wherein the plurality of material layers includes a first material layer and a second material layer, wherein the second material layer is provided under the first material layer; patterning the first material layer located over the bottom of the vertical hole to form a first opening, wherein the first opening exposes the second material layer; and patterning the second material layer exposed by the first opening using a difference in an etch rate between the first material layer and the second material layer.

Abstract: An electronic component includes a plurality of dipoles, each comprising an island solid with a base, a first electrode arranged at the top of the island and a second electrode arranged on the base. Its manufacturing includes forming, on the base, a layer of a material capable of being etched by means of a predetermined isotropic etching, forming, over the layer of material, solid patterns made of electrically-conductive material and inert to said etching, applying the isotropic etching of the thickness of material between said solid patterns to form islands totally overlooked by said solid patterns, and depositing electrically-conductive material on top of and between the islands to form the first and second electrodes of the dipoles.

Abstract: Isolated and bulk semiconductor devices formed on a same bulk substrate and methods to form such devices are described. For example, a semiconductor structure includes a first semiconductor device having a first semiconductor body disposed on a bulk substrate. The first semiconductor body has an uppermost surface with a first horizontal plane. The semiconductor structure also includes a second semiconductor device having a second semiconductor body disposed on an isolation pedestal. The isolation pedestal is disposed on the bulk substrate. The second semiconductor body has an uppermost surface with a second horizontal plane. The first and second horizontal planes are co-planar.

Abstract: A package including a first die embedded in a reconstructed wafer obtainable by the known FO-WLP or eWLB technologies is disclosed. In one aspect and in addition to the first die, a Through Substrate Via insert is embedded in the wafer, the TSV insert being a separate element, possibly a silicon die with metal filled vias interconnecting contacts on the front and back sides of the insert. A second die is mounted on the back side of the substrate, with contacts on the second die in electrical connection with the TSV insert's contacts on the back side of the substrate. On the front side of the substrate, a lateral connecting device is mounted which interconnects the TSV insert's contacts on the front side of the substrate to contacts on the front side of the first die. The lateral connecting device and the TSV insert thereby effectively interconnect the contacts on the first and second dies.