Abstract: A thin-film transistor substrate manufacturing method includes sequentially forming, on a backing, a gate electrode, a gate insulation layer, a source electrode and an active layer, a passivation layer, a drain electrode, and a pixel electrode. Orthogonal projections of the gate electrode, the gate insulation layer, the source electrode and the active layer, the passivation layer, the drain electrode, and the pixel electrode on the backing that are concentric centro-symmetric patterns. Also provided re a thin-film transistor substrate and a liquid crystal panel including the thin-film transistor substrate. The thin-film transistor substrate manufacturing method, the thin-film transistor substrate and the liquid crystal panel including the thin-film transistor substrate allow electrical property of a thin-film transistor consistent in all bending directions and make the thin-film transistor not easily subjected to stress damage during bending so as to improve the reliability of the thin-film transistor.

Abstract: A method of forming a plurality of semiconductor devices includes applying a tape material to a back side of a semiconductor device having a silicon layer on the back side and a circuitry layer on the front side, lasing with an infrared laser the silicon layer through the tape material, lasing with a second laser the circuitry layer, and expanding the tape material for form a plurality of semiconductor devices. The second layer may be an ultraviolet laser. The lasers may be irradiated in a pattern on the bottom side and the top side. The second layer may form a groove in the circuitry layer that does not penetrate the silicon layer. The infrared laser may cleave a portion of the silicon lattice of the silicon layer. A coating may be applied to the circuitry layer prior to being irradiated with the second laser.

Abstract: The present disclosure provides a method that includes coating an edge portion of a wafer by a first chemical solution including a chemical mixture of an acid-labile group, a solubility control unit and a thermal acid generator; curing the first chemical solution to form a first protecting layer on the edge portion of the wafer; coating a resist layer on a front surface of the wafer; removing the first protecting layer by a first removing solution; and performing an exposing process to the resist layer.

Abstract: According to one embodiment, a method for fabricating a semiconductor device is provided. The method for fabricating the semiconductor device includes three steps of a providing step, a bonding step, and a thinning step. In the providing step, a mitigation layer that mitigates warping of the device substrate being thinned by grinding is provided on the supporting substrate. In the bonding step, the device substrate is bonded to the supporting substrate on which the mitigation layer is provided. In the thinning step, the device substrate supported by the supporting substrate is thinned by grinding.

Abstract: A thin Ge layer is formed between an SiGe intrinsic base and single-crystal Si extrinsic base structures to greatly simplify the fabrication of raised-base SiGe heterojunction bipolar transistors (HBTs). The fabrication process includes sequentially depositing the SiGe intrinsic base, the Ge, and Si extrinsic base layers as single-crystal structures over a patterned silicon wafer while the wafer is maintained inside a reaction chamber. The Ge layer subsequently functions as an etch stop, and protects the crystallinity of the underlying SiGe intrinsic base material during subsequent dry etching of the Si extrinsic base layer, which is performed to generate an emitter window. A wet etch then removes residual Ge from the emitter window to expose a contact portion of the SiGe layer surface without damage. A polysilicon emitter structure is formed in the emitter window, and then salicide is formed over the base stacks to encapsulate the SiGe and Ge structures.

Abstract: Generally, the present disclosure is directed to a method for forming a FinFET device that may be used in designs that include both tight and relaxed fin pitches. The method for forming the fins includes: forming a first layer of doped silicate glass above a semiconductor wafer and within a plurality of recesses located adjacent the fins; forming a first layer of nitride above the first doped silicate glass layer; and forming a conformal oxide layer above the first nitride layer, substantially filling relatively narrow recesses between fins having a tight pitch and lining relatively wide recesses between fins having a relaxed pitch.

Abstract: In a semiconductor device, an AlGaN layer includes a first AlGaN layer and a second AlGaN layer. The second AlGaN layer is positioned between a gate structure portion and a drain electrode and is divided into multiple parts in an arrangement direction in which the gate structure portion and the drain electrode are arranged. A second Al mixed crystal ratio of the second AlGaN layer is less than a first Al mixed crystal ratio of the first AlGaN layer. Accordingly, the semiconductor device is a normally-off-type device and is capable of restricting a decrease of a breakdown voltage and an increase of an on-resistance.

Abstract: A method for forming gate cuts during RMG processing and the resulting device are provided. Embodiments include forming Si fins over a substrate; forming a STI layer over the substrate and recessed, exposing upper portions of the Si fins; forming polysilicon dummy gate electrodes perpendicular to the Si fins, separated by STI regions, on the upper portions of the Si fins and on the STI layer between the Si fins; forming a hardmask over the polysilicon dummy gate electrodes; etching through the hardmask and polysilicon dummy gate electrodes forming cavities between some of the Si fins; oxidizing polysilicon exposed on sides of the cavities and any residual polysilicon remaining at a bottom of one or more of the cavities; filling the cavities with SiN; removing the polysilicon dummy gate electrodes; and forming RMGs.

Abstract: The subject matter disclosed herein relates to semiconductor power devices, such as silicon carbide (SiC) power devices. In particular, the subject matter disclosed herein relates to shielding regions in the form of channel region extensions for that reduce the electric field present between the well regions of neighboring device cells of a semiconductor device under reverse bias. The disclosed channel region extensions have the same conductivity-type as the channel region and extend outwardly from the channel region and into the JFET region of a first device cell such that a distance between the channel region extension and a region of a neighboring device cell having the same conductivity type is less than or equal to the parallel JFET width. The disclosed shielding regions enable superior performance relative to a conventional stripe device of comparable dimensions, while still providing similar reliability (e.g., long-term, high-temperature stability at reverse bias).

Abstract: A method for polymerizing a composition including hydridosilanes and subsequently using the polymers to produce silicon containing layers, comprising the following steps: a) providing a substrate; b) providing a composition including at least one hydridosilane that is dissolved in at least one organic and/or inorganic solvent, or including at least one hydridosilane that is already present in liquid form without solvent, wherein the hydridosilanes comprise at least one linear and/or one branched hydridosilane of the general formula SinH2n+2, where n?3, and/or a cyclic hydridosilane of the general formula SinH2n, where n?3; c) polymerizing the composition from step b) by way of acoustic cavitation; and d) coating the surface of the substrate with reaction products from step c).

Abstract: An array substrate for a display device is disclosed. The array substrate includes a substrate comprising a plurality of subpixels, at least one of which is a white subpixel. The array substrate also includes an insulating layer disposed on the substrate in each of the subpixels and a plurality of color filter layers disposed on the insulating layer, each of the color filter layers being disposed respectively in a corresponding one of the subpixels. At least two of the color filter layers have a same color and are respectively disposed in the white subpixel and in at least one of the subpixels adjacent to the white subpixel. The insulating layer has a slope at a boundary between the white subpixel and the at least one of the subpixels adjacent to the white subpixel.

Abstract: A method of manufacturing a semiconductor package according to the present inventive concepts comprises preparing a printed circuit board (PCB) including a protected layer, exposing a portion of the protected layer from the insulating layer, forming a solder ball land by processing the exposed surface of the protected layer, forming a solder ball on the solder ball land, and mounting a semiconductor chip on the solder ball formed on the PCB. The solder balls include copper of about 0.01 wt % to about 0.5 wt %.

Abstract: A novel plasma process is introduced as an improvement over conventional plasma processes during formation of spacers for FinFET devices. Under this novel plasma process, an oxide layer is grown over sidewall materials and low energy plasma gas is used for the over-etching of the corner areas of the sidewalls. The oxide layer can effectively protect the sidewall materials during the over-etching by the low energy plasma gas and thus to reduce the aforementioned CD losses introduced by the low energy plasma gas. This improved low energy plasma etching technique can protect the fin structure from CD losses as compared to the conventional low energy plasma process, and also avoid damaging fin silicon structure with reduced Si losses as compared to the conventional high energy plasma process.

Abstract: A silicon carbide substrate is composed of silicon carbide, and when a main surface thereof is etched with chlorine gas, the overall length of linear etch-pit groups observed in the main surface is equal to or less than the diameter of the substrate.

Abstract: A method of forming a spacer for a vertical transistor is provided. The method includes forming a fin structure that includes a fin on a semiconductor substrate, forming a source junction or a drain junction at an upper surface of the semiconductor substrate and at a base of the fin and epitaxially growing a rare earth oxide (REO) spacer to have a substantially uniform thickness along respective upper surfaces of the source or drain junction and on opposite sides of the fin structure.

Abstract: An organic light-emitting diode display panel for fingerprint recognition includes a plurality of pixel areas arranged in arrays, the pixel area includes a pixel unit and a fingerprint recognition unit, which are adjacent to each other, the pixel unit is configured to emit colorful image light, the fingerprint recognition unit comprises a sensing light emitting module and a sensing light receiving module, the sensing light emitting module is configured to emit sensing light to a finger, and the sensing light receiving module is configured to receive the sensing light reflected by the finger and convert a light signal of the sensing light into an electric signal. An electronic device is also provided.

Abstract: A trench metal-oxide-semiconductor field effect transistor (TMOSFET) includes a plurality of mesas disposed between a plurality of gate regions. Each mesa includes a drift region and a body region. The width of the mesa is in the order of quantum well dimension at the interface between the gate insulator regions and the body regions The TMOSFET also includes a plurality of gate insulator regions disposed between the gate regions and the body regions, drift regions, and drain region. The thickness of the gate insulator regions between the gate regions and the drain region results in a gate-to-drain electric field in an OFF-state that is substantially lateral aiding to deplete the charge in the drift regions.

Abstract: The semiconductor device including a device isolation layer disposed in a substrate and defining an active region, a first conductive pattern on the active region, an impurity region in the active region on a side of the first conductive pattern, a second conductive pattern on the active region between the impurity region and the first conductive pattern, a first spacer between the first conductive pattern and the second conductive pattern, and a contact plug disposed on and electrically connected to the first conductive pattern may be provided. The second conductive pattern may have a width less than a width of the contact plug.

Abstract: Flash light is emitted from flash lamps to the surface of a semiconductor substrate on which a metal layer has been formed for one second or less to momentarily raise temperature on the surface of the semiconductor substrate including the metal layer and an impurity region to a processing temperature of 1000° C. or more. Heat treatment is performed by emitting flash light to the surface of the semiconductor substrate in a forming gas atmosphere containing hydrogen. By heating the surface of the semiconductor substrate to a high temperature in the forming gas atmosphere for an extremely short time period, contact resistance can be reduced without desorbing hydrogen taken in the vicinity of an interface of a gate oxide film for hydrogen termination.

Abstract: A composition for forming a silica layer including a silicon-containing polymer having a weight average molecular weight of about 20,000 to about 70,000 and a polydispersity index of about 5.0 to about 17.0 and a solvent; a silica layer manufactured using the same; and an electronic device including the silica layer.