Abstract: A semiconductor device includes substrate having a fin structure thereon, a gate structure overlying the fin structure, a polymer block at a corner between the gate structure and the fin structure, and a source/drain region on the fin structure. The polymer block includes a nitridation layer in proximity to a sidewall of the gate structure.

Abstract: An electronic chip, system, and method includes a power block including a power source configured to provide power to components of the electronic chip and a relay circuit coupled to the power source and a ground plane. The electronic chip further includes chip package having a first major side and a second major side, the power block secured to the second major side, the chip package comprising electrical connections, disposed on the second major side, to be secured with respect to a circuit board, and interconnect circuitry, electrically coupling the power block to ground, comprising a plurality of conductive layers, a conductive through hole, electrically connecting a first pair of the plurality of conductive layers, having a first width, and a via, electrically connecting a second pair of the plurality of conductive layers, having a second width less than the first width.

Abstract: At least a portion of a memory cell is formed over a first substrate and at least a portion of a steering element or word or bit line of the memory cell is formed over a second substrate. The at least a portion of the memory cell is bonded to at least a portion of a steering element or word or bit line. At least one of the first or second substrate may be removed after the bonding.

Abstract: A method of manufacturing a dynamic random access memory is provided and includes: forming a hard mask layer on a substrate; forming an opening in the hard mask layer and the substrate; forming a dielectric layer on a sidewall of the opening; forming a first part of a buried word line in a lower part of the opening; forming a hard mask layer on a top surface of the hindering layer, where the hindering layer has overhangs covering top corners of the hard mask layer; depositing a first barrier layer on the substrate through hindrance of the overhangs, where the first barrier layer covers the hindering layer and a top surface of the first part and exposes the dielectric layer on the sidewall of the opening; and forming a first conductive layer in the opening, where a sidewall of the first conductive layer contacts the dielectric layer.

Abstract: The present disclosure relates an integrated chip. The integrated chip includes a polysilicon layer arranged on an upper surface of a base substrate. A dielectric layer is arranged over the polysilicon layer, and an active semiconductor layer is arranged over the dielectric layer. A semiconductor material is arranged vertically on the upper surface of the base substrate and laterally beside the active semiconductor layer.

Abstract: Methods and apparatus for filling features on a substrate are provided herein. In some embodiments, a method of filling features on a substrate includes: depositing a first metallic material on the substrate and within a feature disposed in the substrate in a first process chamber via a chemical vapor deposition (CVD) process at a first temperature; depositing a second metallic material on the first metallic material in a second process chamber at a second temperature and at a first bias power to form a seed layer of the second metallic material; etching the seed layer in the second process chamber at a second bias power greater than the first bias power to form an intermix layer within the feature comprising the first metallic material and the second metallic material; and heating the substrate to a third temperature greater than the second temperature, causing a reflow of the second metallic material.

Abstract: Provided are a wafer cleaning apparatus based on light irradiation capable of effectively cleaning residue on a wafer without damaging the wafer, and a wafer cleaning system including the cleaning apparatus. The wafer cleaning apparatus is configured to clean residue on the wafer by light irradiation and includes: a light irradiation unit configured to irradiate light onto the wafer during the light irradiation; a wafer processing unit configured accommodate the wafer and to control a position of the wafer such that the light is irradiated onto the wafer during the light irradiation; and a cooling unit configured to cool the wafer after the light irradiation has been completed. The light irradiation unit, the wafer processing unit, and the cooling unit are sequentially arranged in a vertical structure with the light irradiation unit above the wafer processing unit and the wafer processing unit above the cooling unit.

Abstract: An embodiment provides a semiconductor device comprising: a semiconductor structure including a first conductive semiconductor layer, a second conductive semiconductor layer, an active layer disposed between the first conductive semiconductor layer and the second conductive semiconductor layer, and a plurality of recesses extending through the second conductive semiconductor layer and the active layer and arranged up to a partial region of the first conductive semiconductor layer; a plurality of first electrodes arranged inside the plurality of recesses and electrically connected to the first conductive semiconductor layer; a second electrode electrically connected to the second conductive semiconductor layer; a first conductive layer electrically connected to the plurality of first electrodes; a second conductive layer electrically connected to the second electrode; and an electrode pad electrically connected to the second conductive layer, wherein the electrode pad comprises a first electrode pad and a seco

Abstract: A method for filling a gap feature on a substrate surface is disclosed. The method may include: providing a substrate comprising a non-planar surface including one or more gap features; depositing a metal oxide film over a surface of the one or more gap features by a cyclical deposition process; contacting the metal oxide with an organic ligand vapor; and converting at least a portion of the metal oxide film to a porous material thereby filling the one or more gap features. Semiconductor structures including a metal-organic framework material formed by the methods of the disclosure are also disclosed.

Abstract: Methods and systems for depositing vanadium and/or indium layers onto a surface of a substrate and structures and devices formed using the methods are disclosed. An exemplary method includes using a cyclical deposition process, depositing a vanadium and/or indium layer onto the surface of the substrate. The cyclical deposition process can include providing a vanadium and/or indium precursor to the reaction chamber and separately providing a reactant to the reaction chamber. The cyclical deposition process may desirably be a thermal cyclical deposition process. Exemplary structures can include field effect transistor structures, such as gate all around structures. The vanadium and/or indium layers can be used, for example, as barrier layers or liners, as work function layers, as dipole shifter layers, or the like.

Abstract: Systems and methods disclosed and contemplated herein relate to manufacturing thin film semiconductors. Resulting thin film semiconductors are particularly suited for applications such as flexible optoelectronics and photovoltaic devices. Broadly, methods and techniques disclosed herein include high-temperature deposition techniques combined with lift-off in aqueous environments. These methods and techniques can be utilized to incorporate thin film semiconductors into substrates that have limited temperature tolerances.

Abstract: An epitaxial structure for a high-electron-mobility transistor includes a substrate, a nucleation layer, a buffer layered unit, a channel layer, and a barrier layer sequentially stacked on one another in such order. The buffer layered unit includes at least one multiple quantum well structure containing a plurality of p-i-n heterojunction stacks. Each of the p-i-n heterojunction stacks includes p-type, i-type, and n-type layers which are alternately stacked along a direction away from the nucleation layer, and which are made of materials respectively represented by chemical formulas of AlxGa(1-x)N, AlyGa(1-y)N, and AlzGa(1-z)N. For each of the p-i-n heterojunction stacks, x gradually decreases and z gradually increases along the direction away from the nucleation layer, and y is consistent and ranges from 0 to 0.7.

Abstract: A method for fabricating memory device is provided. The method includes forming a transistor on a substrate. Further, a contact structure is formed on a source/drain region of the transistor. A conductive layer is formed on the contact structure. Four memory structures are formed on the conductive layer to form a quadrilateral structure.

Abstract: The present disclosure provides a FinFET device. The FinFET device comprises a semiconductor substrate of a first semiconductor material; a fin structure of the first semiconductor material overlying the semiconductor substrate, wherein the fin structure has a top surface of a first crystal plane orientation; a diamond-like shape structure of a second semiconductor material disposed over the top surface of the fin structure, wherein the diamond-like shape structure has at least one surface of a second crystal plane orientation; a gate structure disposed over the diamond-like shape structure, wherein the gate structure separates a source region and a drain region; and a channel region defined in the diamond-like shape structure between the source and drain regions.

Abstract: Semiconductor devices and method of forming the same include recessing sacrificial layers relative to the channel layers, in a stack of vertically aligned, alternating sacrificial layers and channel layers, to form first recesses. A dual-layer dielectric is deposited that includes a first dielectric material formed conformally on surfaces of the recesses and a second dielectric material filling a remainder of the first recesses. The first dielectric material is recessed relative to the second dielectric material to form second recesses. Additional second dielectric material is deposited to fill the second recesses. The second dielectric material and the additional second dielectric material is etched away to create air gaps.

Abstract: Provided is a method for manufacturing a semiconductor device, including: forming a conductive layer on the first dielectric layer; forming a recess in the conductive layer; performing a first etching process to round a top corner of the recess; performing a second etching process to remove the conductive layer exposed from a bottom surface of the recess and thereby forming an opening having a rounding top corner in the conductive layer; and forming a second dielectric layer in the opening.

Abstract: A method of forming a semiconductor device includes forming a first fin and a second fin protruding above a substrate; forming isolation regions on opposing sides of the first fin and the second fin; forming a metal gate over the first fin and over the second fin, the metal gate being surrounded by a first dielectric layer; and forming a recess in the metal gate between the first fin and the second fin, where the recess extends from an upper surface of the metal gate distal the substrate into the metal gate, where the recess has an upper portion distal the substrate and a lower portion between the upper portion and the substrate, where the upper portion has a first width, and the lower portion has a second width larger than the first width, the first width and the second width measured along a longitudinal direction of the metal gate.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to a wafer with localized cavity structures and methods of manufacture. A structure includes a bulk substrate with localized semiconductor on insulator (SOI) regions and bulk device regions, the localized SOI regions includes multiple cavity structures and substrate material of the bulk substrate.

Abstract: A light emitting device including a substrate, a first semiconductor layer disposed on the substrate, a mesa including a second semiconductor layer and an active layer disposed on the first semiconductor layer, a first contact electrode contacting the first semiconductor layer, a second contact electrode contacting the second semiconductor layer, a passivation layer covering the first contact electrode, the mesa, and the second contact electrode, and including a first opening disposed on the first contact electrode and a second opening disposed on the second contact electrode, and first and second bump electrodes electrically connected to the first and second contact electrodes through the first and second openings, respectively, in which the first and second bump electrodes are disposed on the mesa, the passivation layer is disposed between the first bump electrode and the second contact electrode, and the first contact electrode includes an alloy layer.

Abstract: The present disclosure provides a method for forming a semiconductor structure. The method includes the following operations. A metal layer is formed. An adhesion-enhancing layer is formed over the metal layer by a silicide operation. A dielectric stack is formed over the adhesion-enhancing layer. A trench is formed in the dielectric stack by removing a portion of dielectric stack aligning with the metal layer. A barrier layer is formed conforming to the sidewall of the trench. A high-k dielectric layer is formed conforming to the barrier layer. A contact is formed in the trench and be connected to the metal layer.