A semiconductor device includes: a substrate including an active region and a device isolation region; a flat plate structure formed on the substrate; an oxide semiconductor layer covering a top surface of the flat plate structure and continuously arranged on a top surface of the substrate in the active region and the device isolation region; a gate structure arranged on the oxide semiconductor layer and including a gate dielectric layer and a gate electrode; and a source/drain region arranged on both sides of the gate structure and formed in the oxide semiconductor layer, in which, when viewed from a side cross-section, an extending direction of the flat plate structure and an extending direction of the gate structure cross each other.

A drive backplane and a display panel are provided, the drive backplane includes: a substrate; and an oxide thin film transistor arranged on the substrate, wherein the oxide thin film transistor includes: an oxide active layer; a first gate structure disposed on a side of the oxide active layer away from the substrate; and a second gate structure disposed between the oxide active layer and the substrate; wherein at least one of the first gate structure and the second gate structure comprises a plurality of gate electrodes spaced apart along a direction in which the oxide active layer extends.

Disclosed is a display apparatus including a first thin film transistor (TFT) and a second thin film transistor having a bottom gate structure and including an oxide semiconductor layer. The first TFT may be used as a switching device and the second TFT may be used as a driving device, and these TFTs have different operation properties from each other. One or more embodiments of the present disclosure provides a method of arranging a plurality of TFTs having different properties in a display apparatus. This not only provides a display apparatus with TFTs integrated at a high density but also an efficient way of driving the display apparatus.

A display apparatus includes a first TFT in a display area including a first semiconductor pattern including a polysilicon, a first gate electrode overlapping with the first semiconductor pattern under conditions that a first gate insulating layer is interposed, and first source and drain electrodes connected to the first semiconductor pattern, a second TFT in the display area including a second semiconductor pattern including a first oxide semiconductor, a second gate electrode overlapping with the second semiconductor pattern under conditions that second and third gate insulating layers are interposed, second source and drain electrodes connected to the second semiconductor pattern, and a third TFT in a non-display area including a third semiconductor pattern including a second oxide semiconductor, a third gate electrode overlapping with the third semiconductor pattern under conditions that the third gate insulating layer is interposed, and third source and drain electrodes connected to the third semiconductor pattern.

A display device includes a buffer layer disposed on a substrate and comprising a first buffer film, and a second buffer film, wherein the first buffer film and the second buffer film are sequentially stacked in a thickness direction of the display device; a semiconductor pattern disposed on the buffer layer; a gate insulating layer disposed on the semiconductor pattern; and a gate electrode disposed on the gate insulating layer, wherein the first buffer film and the second buffer film comprise a same material, and a density of the first buffer film is greater than a density of the second buffer film.

A method for making a semiconductor memory device comprising a plurality of memory cells for storing one or more data values, the method comprising: exposing a pattern on a wafer for creating structures for a plurality of memory cells for the semiconductor memory device, wherein the pattern is exposed by means of one or more charged particle beams; and varying an exposure dose of the one or more charged particle beams during exposure of the pattern to generate a set of one or more non-common features in one or more structures of at least one of the memory cells, so that the structures of the at least one memory cell differ from the corresponding structures of other memory cells of the semiconductor memory device.

A method for making a semiconductor memory device comprising a plurality of memory cells for storing one or more data values, the method comprising; exposing a pattern on a wafer for creating structures for a plurality of memory cells for the semiconductor memory device, wherein the pattern is exposed by means of one or more charged particle beams; and varying an exposure dose of the one or more charged particle beams during exposure of the pattern to generate a set of one or more non-common features in one or more structures of at least one of the memory cells, so that the structures of the at least one memory cell differ from the corresponding structures of other memory cells of the semiconductor memory device.

Embodiments of a method for forming a three-dimensional (3D) memory device includes the following operations. First, a channel hole is formed in a stack structure of a plurality first layers and a plurality of second layers alternatingly arranged over a substrate. A semiconductor channel is formed by filling the channel hole with a channel-forming structure. The plurality of first layers is removed. A plurality of conductor layers is formed from the plurality of second layers. Further, a gate-to-gate dielectric layer is formed between the adjacent conductor layers, the gate-to-gate dielectric layer including at least one sub-layer of silicon oxynitride.

An imaging device according to an embodiment of the present disclosure includes: a first semiconductor substrate (100) provided with pixels including a photoelectric conversion element (PD) and floating diffusion (FD) that temporarily holds a charge output from the photoelectric conversion element (PD); and a semiconductor layer (200Y) provided on the first semiconductor substrate (100) via an insulating film (123), the semiconductor layer (200Y) including a readout circuit unit (539) that reads out the charge held in the floating diffusion (FD) and outputs a pixel signal, in which the semiconductor layer (200Y) is formed of an organic semiconductor material.

The present invention provides a processing circuit including logic cells and a thermal sensor. The thermal sensor is positioned within the logic cells and surrounded by the logic cells, and the logic cells and the thermal sensor are all implemented by core devices.