The disclosure provides a liquid crystal display panel, an array substrate and a manufacturing method thereof. In the method, controllable resistance spacer layers are formed on at least one of a source doped region and a drain doped region of a low temperature polysilicon active layer, wherein when a turn-on signal is not applied to the gate layer, the controllable resistance spacer layers serve as a blocking action for a flowing current, and when the turn-on signal is applied to the gate layer, the controllable resistance spacer layers serve as a conducting action for the flowing current, such that a contact region formed of the controllable resistance spacer layers is connected the corresponding source layer and the corresponding drain through the controllable resistance spacer layers. Therefore, the disclosure is capable of effectively decreasing a leakage of a thin film transistor.

The present invention provides a method for manufacturing the N-type TFT, which includes subjecting a light shielding layer to a grating like patternization treatment for controlling different zones of a poly-silicon layer to induce difference of crystallization so as to have different zones of the poly-silicon layer forming crystalline grains having different sizes, whereby through just one operation of ion doping, different zones of the poly-silicon layer have differences in electrical resistivity due to difference of grain size generated under the condition of identical doping concentration to provide an effect equivalent to an LDD structure for providing the TFT with a relatively low leakage current and improved reliability. Further, since only one operation of ion injection is involved, the manufacturing time and manufacturing cost can be saved, damages of the poly-silicon layer can be reduced, the activation time can be shortened, thereby facilitating the manufacture of flexible display devices.

After formation of a disposable gate structure, a raised active semiconductor region includes a vertical stack, from bottom to top, of an electrical-dopant-doped semiconductor material portion and a carbon-doped semiconductor material portion. A planarization dielectric layer is deposited over the raised active semiconductor region, and the disposable gate structure is replaced with a replacement gate structure. A contact via cavity is formed through the planarization dielectric material layer by an anisotropic etch process that employs a fluorocarbon gas as an etchant. The carbon in the carbon-doped semiconductor material portion retards the anisotropic etch process, and the carbon-doped semiconductor material portion functions as a stopping layer for the anisotropic etch process, thereby making the depth of the contact via cavity less dependent on variations on the thickness of the planarization dielectric layer or pattern factors.

The disclosure relates to a semiconductor device and methods of forming same. A representative structure for a semiconductor device comprises a substrate; a nanowire structure protruding from the substrate having a channel region disposed between a source region and a drain region; a pair of silicide regions extending into opposite sides of the source region, wherein each of the pair of silicide regions comprise a vertical portion adjacent to the source region and a horizontal portion adjacent to the substrate; and a metal gate surrounding a portion the channel region.

A structure and method for fabricating a semiconductor device is described. A device structure including a gate structure, a source region and a drain region is disposed on a first surface of a substrate. Contact holes are etched through the source and drain regions and through a first portion of the substrate. The contact holes are filled with a conductive material to produce contact studs coupled to the source and drain regions. A second portion of the substrate is removed. A surface of the contact studs is exposed through a second surface of the substrate opposite to the gate structure for connection to a wiring layer disposed over the second surface of the substrate.

A structure of a semiconductor device is described. A semiconductor device includes a transistor which further includes a gate structure, a source region and a drain region disposed on a first surface of a substrate. A wiring layer of conductive material is disposed over a second surface of the substrate. The second surface of the substrate is located opposite to the first surface of the substrate. A set of contact studs including a first contact stud which extends completely through the source region and through the substrate to a first respective portion of the wiring layer. The set of contact studs also includes a second contact stud which extends completely through the drain region and through the substrate to a second respective portion of the wiring layer.

A structure of a semiconductor device is described. In one aspect of the invention, a FinFET semiconductor device includes a FinFET transistor which includes a source region and a drain region disposed in a fin on a first surface of a substrate. A gate structure is disposed over a central portion of the fin. A wiring layer of conductive material is disposed over a second surface of the substrate which is opposite to the first surface of the substrate. A set of contact studs include a first contact stud which extends completely through the height of the fin in the source region and the substrate to the wiring layer. The set of contact studs also includes a second contact stud which extends completely through the height of the fin in the drain region and the substrate to the wiring layer. In other aspects of the invention, the device is a Nanosheet device or an inverter.

Embodiments of the disclosure provide an array substrate having via-hole conductive layer and display device. The array substrate includes: a thin film transistor; a passivation layer, covering the thin film transistor, the passivation layer having a via hole and the via hole exposing at least a portion of a drain electrode of the thin film transistor; a via-hole conductive layer, covering the portion of the drain electrode exposed at the via hole and connected to the drain electrode, and a reflectivity of the via-hole conductive layer being lower than a reflectivity of the drain electrode; and a pixel electrode, connected with the drain electrode through the via-hole conductive layer.

The present disclosure provides an array substrate and a method of manufacturing the same and a display apparatus in which the array substrate is applied. In one embodiment, the method of manufacturing an array substrate at least includes the steps of: forming a first electrode layer, a metal gate layer and a first layer of non-oxide insulation material, the first layer of non-oxide insulation material being formed on an upper surface of the metal gate layer; forming, by using one patterning process, a pattern including a first electrode and a gate such that, after completion of the patterning process, a first non-oxide insulation layer is further formed on the gate and a first sub-electrode belonging to the first electrode layer is further formed below the gate. This method of manufacturing the array substrate is simple, which facilitates mass production of the array substrate as well as the display apparatus.

After forming a buried nanowire segment surrounded by a gate structure located on a substrate, an epitaxial source region is grown on a first end of the buried nanowire segment while covering a second end of the buried nanowire segment and the gate structure followed by growing an epitaxial drain region on the second end of the buried nanowire segment while covering the epitaxial source region and the gate structure. The epitaxial source region includes a first semiconductor material and dopants of a first conductivity type, while the epitaxial drain region includes a first semiconductor material different from the first semiconductor material and dopants of a second conductivity type opposite the first conductivity type.