A structure of 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.

Exemplary embodiments of the present invention relate to a panel and a display device including the same, the panel including a substrate, a signal line arranged on the substrate, the signal line configured to transmit a driving signal, an insulating layer arranged on the signal line, and a pixel electrode and a contact assistant arranged on the insulating layer. The contact assistant is electrically connected to a portion of the signal line, the contact assistant includes indium zinc oxide doped with a metal oxide not including indium or zinc, and the metal oxide has a smaller Gibbs free energy than zinc oxide.

An AMOLED back plate includes a substrate on which a buffer layer and a poly-silicon section are sequentially formed. A source and a drain are respectively formed of P-type heavy doped micro silicon on the poly-silicon section that have edges facing and spaced from each other to define a channel therebetween. A gate isolation layer is formed on the buffer layer, the source, the drain and the channel. A gate is formed on the gate isolation layer and has opposite edges that face in directions toward the edges of the source and the drain. The opposite edges of the gate are spaced from the edges of the source and the drain by predetermined spacing distance in horizontal directions so as to prevent the gate from overlapping the source and the drain.

A semiconductor device includes a semiconductor substrate comprising a contact region, a silicide present on the contact region, a dielectric layer present on the semiconductor substrate, the dielectric layer comprising an opening to expose a portion of the contact region, a conductor present in the opening, a barrier layer present between the conductor and the dielectric layer, and a metal layer present between the barrier layer and the dielectric layer, wherein a Si concentration of the silicide is varied along a height of the silicide.

A method for forming contact silicide for a semiconductor structure. In one embodiment, a dielectric layer is formed over a p-type region of a semiconductor structure comprising a gate stack and source and drain regions. The source and drain regions are formed within a semiconductor layer. First and second contact trenches are formed within the dielectric layer exposing at least a portion of the source region and a portion of the drain region, respectively. First and second metal layers are formed within the first and second contact trenches. The second metal layer includes a metallic material that is different from a metallic material of the first meal layer. The metallic materials of the first and second metal layers in a lower region of the first and second contact trenches are intermixed. A silicide is formed within the source and drain regions from the semiconductor layer and the intermixed metallic materials.

The present invention provides a manufacture method of an AMOLED back plate and a structure thereof. The manufacture method of the AMOLED back plate is: sequentially deposing a buffer layer (2), an amorphous silicon layer (2) on a substrate (1), and crystallizing and converting the amorphous silicon layer to be a polysilicon layer, and patterning the polysilicon layer, and then deposing a P type heavy doped micro silicon layer (P+uc-Si), and implementing a photo process to define a position of a channel (40), and etching the P type heavy doped micro silicon layer (P+uc-Si) to form a source/a drain (41), and thereafter, sequentially forming a gate isolation layer (5), a gate (61), an interlayer insulation layer (7), a metal source/a metal drain (81), a flat layer (9), an anode (10), a pixel definition layer (11) and a photo spacer (12); the source/the drain (41) and the gate (61) do not overlap in the horizontal direction and are mutually spaced. The method can improve the electrical property of the drive TFT to make the conductive current higher, and the leakage current lower, and diminish the image sticking for raising the display quality of the AMOLED.

An array substrate for a liquid crystal display (LCD) device include: a substrate; a gate line formed in one direction on one surface of the substrate; a data line crossing the gate line to define a pixel area; a thin film transistor (TFT) configured at a crossing of the gate line and the data line; a pixel electrode formed at a pixel region of the substrate; an insulating film formed on the entire surface of the substrate including the pixel electrode and the TFT, including a first insulating film formed of a high temperature silicon nitride film and a second insulating film formed of a low temperature silicon nitride film, and having a contact hole having an undercut shape exposing the pixel electrode; a pixel electrode connection pattern formed within the contact hole having an undercut shape and connected with the pixel electrode and the TFT; and a plurality of common electrodes separately formed on the insulating film.

The invention relates to a method for fabricating an array substrate, an array substrate and a display device. The method for fabricating an array substrate may comprise: forming a pattern including a source electrode, a drain electrode and a data line; forming a non-crystalline semiconductor thin film layer; and performing annealing, so as to convert only the non-crystalline semiconductor thin film layer on the source electrode, drain electrode and data line to a metal semiconductor compound. By converting only the non-crystalline semiconductor thin film layer on the source electrode, drain electrode and data line into a metal semiconductor compound, the resulting metal semiconductor compound may prevent oxidative-corrosion of the metal thin film layer, such as a low-resistance metal (e.g., Cu or Ti) layer, in the subsequent procedures, which is favorable for the fabrication of a metal oxide thin film transistor using Cu or Ti.

The invention relates to a method for fabricating an array substrate, an array substrate and a display device. The method for fabricating an array substrate may comprise: forming a metal thin film layer for a source electrode, a drain electrode and a data line; forming a non-crystalline semiconductor thin film layer on the metal thin film layer; and performing annealing, so as to at least partly convert the non-crystalline semiconductor thin film layer into a metal semiconductor compound. By at least partly converting the non-crystalline semiconductor thin film layer into a metal semiconductor compound, the resulting metal semiconductor compound may prevent oxidative-corrosion of the metal thin film layer, such as a low-resistance metal (e.g., Cu or Ti) layer, in the subsequent procedures, which is favorable for the fabrication of a metal oxide thin film transistor using Cu or Ti.

A semiconductor device including: a first level including a first single crystal silicon layer, a plurality of first transistors, and input/output circuits; a first metal layer; a second metal layer which includes a power delivery network; where interconnection of the plurality of first transistors includes the first and second metal layers; a second level including a plurality of metal gate second transistors and first array of memory cells, disposed over the first level; a third level including a plurality of metal gate third transistors and a second array of memory cells, disposed over the second level; a via disposed through the second and third levels; a third metal layer disposed over the third level; a fourth metal layer disposed over the third metal layer; and a fourth level disposed over the fourth metal layer and including a second single crystal silicon layer.