Provided is a hydrogenation annealing method using a microwave, which performs hydrogenation annealing at a low temperature and with low power in a manufacturing process of a thin film transistor (TFT) for a display device. The hydrogenation annealing method is constituted by a loading step of loading a device requiring hydrogenation annealing into a chamber and an annealing step of irradiating a microwave having a frequency in an industrial scientific medical (ISM) band into the chamber into which the device is loaded. As hydrogenation annealing is performed at a low temperature by using the microwave for an oxide semiconductor TFT or LTPS having very large electron mobility, high integrated energy is transmitted to the device by the microwave, thereby implementing recoupling of hydrogen atoms which have been performed only at a high temperature, even at a low temperature.

In various embodiments, electronic devices such as touch-panel displays incorporate interconnects featuring a conductor layer and, disposed above the conductor layer, a capping layer comprising an alloy of Cu and one or more refractory metal elements selected from the group consisting of Ta, Nb, Mo, W, Zr, Hf, Re, Os, Ru, Rh, Ti, V, Cr, and Ni.

The present invention provides a manufacture method of a TFT substrate structure and a TFT substrate structure. In the manufacture method of the TFT substrate structure, as manufacturing the gate, a plurality of metal sections distributed in spaces are formed at two sides of the gate, and the gate and the plurality of metal sections are employed to be a mask to implement ion implantation to the polysilicon layer. In the TFT substrate structure according to the present invention, the undoped areas are formed among the n-type heavy doping areas while forming the n-type heavy doping areas at the polysilicon layer.

This technology relates to an image sensor. The image sensor may include a substrate including a photoelectric conversion element; a pillar formed over the photoelectric conversion element and having a concave-convex sidewall; a channel film formed along a surface of the pillar and for having at least one end coupled to the photoelectric conversion element; and a transfer gate formed over the channel film.

A thin-film transistor, method of manufacturing the same, and a display apparatus are provided. The thin-film transistor includes a first active layer, a source, a drain, a gate, and a second active layer, the source, the drain, the gate are disposed on the first active layer with spacing, the gate is located between the source and the drain, the second active layer is disposed on the gate, the source, and the drain, the source and the drain are both respectively connected to the first active layer and the second active layer, and the gate is respectively insulated from the first active layer, the second active layer, the source, and the drain. When a voltage is applied to the gate, the source and the drain may be conducting via the first and second active layer. Therefore, a larger current may flow between the source and the drain.

A TFT, OLED display including the same, and manufacturing method thereof are disclosed. In one aspect, the TFT includes a first gate electrode formed over a substrate and a first insulating layer formed over the substrate and the first gate electrode. A semiconductor layer is formed over the first insulating layer, the semiconductor layer at least partially overlapping the first gate electrode. A second insulating layer is formed over the first insulating layer and the semiconductor layer, the first and second insulating layers having a pair of connection holes formed therethrough. A second gate electrode is electrically connected to the first gate electrode via the connection holes, the connection holes respectively exposing portions of the first gate electrode. Source and drain electrodes are formed over a third insulating layer and electrically connected to the semiconductor layer via the contact holes, the contact holes respectively exposing portions of the semiconductor layer.

The present disclosure discloses a method for preparing an array substrate, an array substrate and a display panel, wherein the method comprises: forming a buffer layer on a substrate in a first region and a second region, wherein the buffer layer has a groove located in the second region; forming a first indium oxide thin film on the buffer layer in the first region; forming a second indium oxide thin film in the groove; performing a reduction process on the second indium oxide thin film to obtain indium particles; forming an amorphous silicon thin film in the groove, and inducing the amorphous silicon of the amorphous silicon thin film to form microcrystalline silicon at a preset temperature by using the indium particles; and removing the indium particles in the microcrystalline silicon to form a microcrystalline silicon semiconductor layer of the microcrystalline silicon thin film transistor.

The disclosure relates to a CMOS structure and a manufacturing method thereof. The CMOS structure includes a substrate and an N-type TFT and a P-type TFT on the substrate. The N-type TFT includes a first gate electrode, a first active layer, and a first gate dielectric layer therebetween. The first active layer includes a first semiconductor layer, a second semiconductor layer of the N-type, and a third semiconductor layer of the N-type which are located at opposite ends of the first semiconductor layer and sequentially stacked in a direction away from the first gate dielectric layer. An N-type doping concentration of the second semiconductor layer is smaller than that of the third semiconductor layer. The P-type TFT includes a fifth semiconductor layer and a sixth semiconductor layer. A P-type doping concentration of the fifth semiconductor layer is smaller than that of the sixth semiconductor layer.

A method for the selective formation of epitaxial layers is described herein. In the method, epitaxial layers are deposited to form source and drain regions around a horizontal gate all around (hGAA structure). The method includes co-flowing a combination of chlorinated silicon containing precursors, antimony containing precursors, and n-type dopant precursors. The resulting source and drain regions are selectively grown from crystalline nanosheets or nanowires of the hGAA structure over the non-crystalline gate structure and dielectric layers. The source and drain regions are predominantly grown in a <110> direction.

An active element and a manufacturing method thereof are provided. The active element includes a substrate, a switching bottom gate and a driving bottom gate disposed on the substrate, a first gate insulating layer disposed on the substrate and covering the switching bottom gate and the driving bottom gate, a switching channel and a driving channel disposed on the first gate insulating layer, a second gate insulating layer disposed on the first gate insulating layer and covering the switching channel and the driving channel, and a switching top gate and a driving top gate disposed on the second gate insulating layer. The driving channel has a low potential end electrically connected to the driving bottom gate. A thickness of the second gate insulating layer is greater than a thickness of the first gate insulating layer. The switching top gate is electrically connected to the switching bottom gate.