Abstract: In one aspect, a method of enhancing semiconductor chip process variability and lifetime reliability through a three-dimensional (3D) integration applied to electronic packaging is disclosed. Also provided is an arrangement for implementing the inventive method. In another aspect, a method and on-chip controller are disclosed for enhancing semiconductor chip process variability and lifetime reliability through a three-dimensional (3D) integration applied to electronic packaging. Also provided is an on-chip reliability/variability controller arrangement for implementing the inventive method. In yet another aspect, base semiconductor chips, each comprising a plurality of chiplets, are manufactured and tested. For a base semiconductor chip having at least one non-functional chiplet, at least one repair semiconductor chiplet chiplet is vertically stacked. A functional multi-chip assembly is formed, which provides the same functionality as a base semiconductor chip in which all chiplets are functional.

Abstract: In accordance with an embodiment a structure can include a monolithically integrated trench field-effect transistor (FET) and Schottky diode. The structure can include a first gate trench extending into a semiconductor region, a second gate trench extending into the semiconductor region, and a source region flanking a side of the first gate trench. The source region can have a substantially triangular shape, and a contact opening extending into the semiconductor region between the first gate trench and the second gate trench. The structure can include a conductor layer disposed in the contact opening to electrically contact the source region along at least a portion of a slanted sidewall of the source region, and the semiconductor region along a bottom portion of the contact opening. The conductor layer can form a Schottky contact with the semiconductor region.

Abstract: Micro-Electro-Mechanical System (MEMS) structures, methods of manufacture and design structures are disclosed. The method includes layering metal and insulator materials on a sacrificial material formed on a substrate. The method further includes masking the layered metal and insulator materials. The method further includes forming an opening in the masking which overlaps with the sacrificial material. The method further includes etching the layered metal and insulator materials in a single etching process to form the beam structure, such that edges of the layered metal and insulator material are aligned. The method further includes forming a cavity about the beam structure through a venting.

Abstract: Disclosed is a package method for electronic components by a thin substrate, comprising: providing a carrier; forming at least one metal layer and at least one dielectric layer on the carrier for manufacturing the thin substrate, and the thin substrate comprises at least one package unit for connecting at least one chip; forming at least one pad layer on a surface of the thin substrate; parting the thin substrate from the carrier; performing test to the thin substrate to weed out the package unit with defects in the at least one package unit and select the package units for connecting the chips; connecting the chips with the selected package units by flip chip bonding respectively. Accordingly, the yield of the entire package process can be improved and the pointless manufacture material cost can be reduced.

Abstract: A method of producing an organic semiconductor device is provided in which a layer composed of an organic semiconductor having excellent crystallinity and orientation in a low-temperature region can be formed, and the device can be produced in the air.

Abstract: Provided are semiconductor memory devices and the methods of fabricating the same. The method may include forming a plurality of diode patterns in each of a plurality of first trenches, each of the plurality of first trenches including at least two active regions, the plurality of diode patterns occupying a plurality of spaces, treating the plurality of diode patterns to form a plurality of semiconductor patterns in each of the plurality of spaces, removing portions of the plurality of semiconductor patterns to form a recess in each of the plurality of spaces, treating the of the plurality of semiconductor patterns to form a plurality of diodes in each of the plurality of spaces, forming a bottom electrode on each of the plurality of diodes, forming a plurality of memory elements on each of the bottom electrodes, and forming a plurality of upper interconnection lines on the plurality of memory elements.

Abstract: A method of forming a display substrate includes forming an array layer on a substrate, forming a passivation layer on the array layer, forming a photoresist pattern on the passivation layer corresponding to a gate line, a source line and a thin-film transistor of the array layer, etching the passivation layer using the photoresist pattern as a mask, Non-uniformly surface treating a surface of the photoresist pattern, forming a transparent electrode layer on the substrate having the surface-treated photoresist pattern formed thereon and forming a pixel electrode. The forming a pixel electrode includes removing the photoresist pattern and the transparent electrode layer, such as by infiltrating a strip solution into the surface-treated photoresist pattern.

Abstract: A MOS transistor structure with an in-situ doped source and/or drain and a method for forming the same are provided. The method comprises steps of: providing a substrate; forming a high Ge content layer on the substrate; forming a gate stack on the high Ge content layer and forming a side wall of one or more layers on both sides of the gate stack; etching the high Ge content layer to form a source region and/or a drain region; and forming a source and/or a drain in the source region and/or the drain region respectively by a low-temperature selective epitaxy, and introducing a doping gas during the low-temperature selective epitaxy to heavily dope the source and/or the drain and to in-situ activate a doping element.

Abstract: Organic-adhesive tapes are often used to secure and protect the bumps during wafer processing after bump formation. While residual organic-adhesive tape may remain on the wafer after tape de-lamination, applying a bump template layer on the bumps before laminating the tape allows any residue to be removed afterwards and results in a residue-free wafer.

Abstract: A combined battery and device apparatus and associated method. This apparatus includes a first conductive layer, a battery comprising a cathode layer; an anode layer, and an electrolyte layer located between and electrically isolating the anode layer from the cathode layer, wherein the anode or the cathode or both include an intercalation material, the battery disposed such that either the cathode layer or the anode layer is in electrical contact with the first conductive layer, and an electrical circuit adjacent face-to-face to and electrically connected to the battery. Some embodiments further include a photovoltaic cell and/or thin-film capacitor. In some embodiments, the substrate includes a polymer having a melting point substantially below 700 degrees centigrade. In some embodiments, the substrate includes a glass. For example, some embodiments include a battery deposited directly on the back of a liquid-crystal display (LCD) device.

Abstract: A semiconductor device includes a semiconductor substrate and a via electrode. The via electrode has a first portion on the substrate and extends towards the substrate and has a plurality of spikes that extends from the first portion into the substrate, each of the spikes being spaced apart form one another.

Abstract: Methods of manufacturing semiconductor devices and transistors are disclosed. In one embodiment, a method of manufacturing a semiconductor device includes providing a workpiece comprising a plurality of fins, and forming a semiconductive material over a top surface of the plurality of fins. An etch stop layer is formed over the semiconductive material, and an insulating material is disposed over the etch stop layer. The insulating material and a portion of the etch stop layer are removed from over the plurality of fins. Forming the semiconductive material or forming the etch stop layer are controlled so that removing the portion of the etch stop layer does not remove the etch stop layer between a widest portion of the semiconductive material over the plurality of fins.

Abstract: A coating solution of SOG is applied on a silicon oxynitride film (11) and precured. As a result, moisture contained in the coating solution volatilizes, and an SOG film (12) is formed. Next, a coating solution of SOG is applied on the SOG film (12) and precured. As a result, an SOG film (13) is formed. Thereafter, a coating solution of SOG is applied on the SOG film (13) and precured. As a result, an SOG film (14) is formed. Subsequently, a main cure of the SOG films (12, 13, and 14) is performed. The viscosity of the coating solution of SOG used for forming the SOG film (12) is lower than those of the coating solutions of SOG used for forming the SOG films (13 and 14).

Abstract: A method for fabricating a semiconductor device, comprising: forming n-channel field-effect transistors on a silicon substrate; forming a first insulating film covering the field-effect transistors; shrinking the first insulating film; forming a second insulating film over the first insulating film; and shrinking the second insulating film, wherein the forming an insulating film covering the field-effect transistors and the shrinking the insulating film are repeated a plurality of time.

Abstract: Disclosed is a method for manufacturing an array substrate of an FFS type TFT-LCD, comprising the steps of: forming a first transparent conductive film, a first metal film and an impurity-doped semiconductor film on a transparent substrate sequentially, and then patterning the stack of the films to form patterns including source electrodes, drain electrodes, data lines and pixel electrodes; forming a semiconductor film and patterning it to form a pattern of the impurity-doped semiconductor layer and a pattern of the semiconductor layer including TFT channels; forming an insulating film and a second metal film, and patterning the stack of the films to form patterns including connection holes of the data lines in a PAD region, gate lines, gate electrodes and common electrode lines; forming a second transparent conductive film, and patterning it to form patterns including the common electrode.

Abstract: In a thin film transistor which uses an oxide semiconductor, buffer layers containing indium, gallium, zinc, oxygen, and nitrogen are provided between the oxide semiconductor layer and the source and drain electrode layers.

Abstract: A slurry composition for chemical mechanical polishing (CMP) of a phase-change memory device is provided. The slurry composition comprises deionized water and iron or an iron compound. The slurry composition can achieve high polishing rate on a phase-change memory device and improved polishing selectivity between a phase-change memory material and a polish stop layer (e.g., a silicon oxide film), can minimize the occurrence of processing imperfections (e.g., dishing and erosion), and can lower the etch rate on a phase-change memory material to provide a high-quality polished surface. Further provided is a method for polishing a phase-change memory device using the slurry composition.

Abstract: Embodiments of the present invention generally provide methods and apparatus for material removal using lasers in the fabrication of solar cells. In one embodiment, an apparatus is provided that removes portions of a dielectric layer deposited on a solar cell substrate according to a desired pattern. In certain embodiments, methods for removing a portion of a material via a laser without damaging the underlying substrate are provided. In one embodiment, the intensity profile of the beam is adjusted so that the difference between the maximum and minimum intensity within a spot formed on a substrate surface is reduced to an optimum range. In one example, the substrate is positioned such that the peak intensity at the center versus the periphery of the substrate is lowered. In one embodiment, the pulse energy is improved to provide thermal stress and physical lift-off of a desired portion of a dielectric layer.

Abstract: A method for fabricating a semiconductor device is disclosed. The method includes forming at least one material layer over a substrate; performing an end-cut patterning process to form an end-cut pattern overlying the at least one material layer; transferring the end-cut pattern to the at least one material layer; performing a line-cut patterning process after the end-cut patterning process to form a line-cut pattern overlying the at least one material layer; and transferring the line-cut pattern to the at least one material layer.

Abstract: A thin film can be formed on a substrate at a low temperature with a practicable film-forming rate. There is provided a semiconductor device manufacturing method for forming an oxide or nitride film on a substrate. The method comprises: exposing the substrate to a source gas; exposing the substrate to a modification gas comprising an oxidizing gas or a nitriding gas, wherein an atom has electronegativity different from that of another atom in molecules of the oxidizing gas or the nitriding gas; and exposing the substrate to a catalyst. The catalyst has acid dissociation constant pKa in a range from 5 to 7, but a pyridine is not used as the catalyst.