A semiconductor device includes a first insulating layer over a substrate, a first metal oxide layer over the first insulating layer, an oxide semiconductor layer over the first metal oxide layer, a second metal oxide layer over the oxide semiconductor layer, a gate insulating layer over the second metal oxide layer, a second insulating layer over the second metal oxide layer, and a gate electrode layer over the gate insulating layer. The gate insulating layer includes a region in contact with a side surface of the gate electrode layer. The second insulating layer includes a region in contact with the gate insulating layer. The oxide semiconductor layer includes first to third regions. The first region includes a region overlapping with the gate electrode layer. The second region, which is between the first and third regions, includes a region overlapping with the gate insulating layer or the second insulating layer. The second and third regions each include a region containing an element N (N is phosphorus, argon, or xenon).

A method of forming a vertical finFET and vertical diode device on the same substrate, including forming a channel layer stack on a heavily doped layer; forming fin trenches in the channel layer stack; oxidizing at least a portion of the channel layer stack inside the fin trenches to form a dummy layer liner; forming a vertical fin in the fin trenches with the dummy layer liner; forming diode trenches in the channel layer stack; oxidizing at least a portion of the channel layer stack inside the diode trenches to form a dummy layer liner; forming a first semiconductor segment in a lower portion of the diode trenches with the dummy layer liner; and forming a second semiconductor segment in an upper portion of the diode trenches with the first semiconductor segment, where the second semiconductor segment is formed on the first semiconductor segment to form a p-n junction.

A method of forming a vertical finFET and vertical diode device on the same substrate, including forming a channel layer stack on a heavily doped layer; forming fin trenches in the channel layer stack; oxidizing at least a portion of the channel layer stack inside the fin trenches to form a dummy layer liner; forming a vertical fin in the fin trenches with the dummy layer liner; forming diode trenches in the channel layer stack; oxidizing at least a portion of the channel layer stack inside the diode trenches to form a dummy layer liner; forming a first semiconductor segment in a lower portion of the diode trenches with the dummy layer liner; and forming a second semiconductor segment in an upper portion of the diode trenches with the first semiconductor segment, where the second semiconductor segment is formed on the first semiconductor segment to form a p-n junction.

A method of forming a vertical finFET and vertical diode device on the same substrate, including forming a channel layer stack on a heavily doped layer; forming fin trenches in the channel layer stack; oxidizing at least a portion of the channel layer stack inside the fin trenches to form a dummy layer liner; forming a vertical fin in the fin trenches with the dummy layer liner; forming diode trenches in the channel layer stack; oxidizing at least a portion of the channel layer stack inside the diode trenches to form a dummy layer liner; forming a first semiconductor segment in a lower portion of the diode trenches with the dummy layer liner; and forming a second semiconductor segment in an upper portion of the diode trenches with the first semiconductor segment, where the second semiconductor segment is formed on the first semiconductor segment to form a p-n junction.

Oxide growth of a gate dielectric layer that occurs between processes used in the fabrication of a gate dielectric structure can be reduced. The reduction in oxide growth can be achieved by maintaining the gate dielectric layer in an ambient effective to mitigate oxide growth of the gate dielectric layer between at least two sequential process steps used in the fabrication the gate dielectric structure. Maintaining the gate dielectric layer in an ambient effective to mitigate oxide growth also improves the uniformity of nitrogen implanted in the gate dielectric.

A thin film transistor array substrate includes a pixel electrode layout area, a data electrode layout area, a transparent pixel electrode layer formed in the pixel electrode layout area, a first metal layer, a first dielectric layer, an amorphous silicon layer, a second metal layer, a second dielectric layer formed in the pixel electrode layout area and the data electrode layout area. The first dielectric layer covers the first metal layer. The amorphous silicon layer, the second metal layer and the second dielectric layer are sequentially formed on the first dielectric layer. The transparent pixel electrode layer is connected to the second metal layer through a via hole formed in the pixel electrode area of the second dielectric layer. Moreover, a method for manufacturing the thin film transistor array and a liquid crystal display including the thin film transistor array substrate also are provided.

A thin film transistor array substrate includes a bottom gate disposed on a substrate and a bottom gate insulating layer covering the bottom gate, a semiconductor oxide layer disposed on the bottom gate insulating layer and an etch blocking layer covering the semiconductor oxide layer and including a first via, a drain disposed on the etch blocking layer and contacting with the semiconductor oxide layer through the first via and an insulating protection layer covering the drain, a second via arranged in the insulating protection layer, the etch blocking layer and the bottom gate insulating layer, a top gate disposed on insulating protection layer and contacting with the bottom gate through the second via. A method for manufacturing the thin film transistor array substrate is also disclosed. The thin film transistor prevents the threshold voltage thereof from being drifted in a case of negative bias illumination stress (NBIS).

To provide a semiconductor device that includes an oxide semiconductor and is miniaturized while keeping good electrical properties. In the semiconductor device, an oxide semiconductor layer filling a groove is surrounded by insulating layers including an aluminum oxide film containing excess oxygen. Excess oxygen contained in the aluminum oxide film is supplied to the oxide semiconductor layer, in which a channel is formed, by heat treatment in a manufacturing process of the semiconductor device. Moreover, the aluminum oxide film forms a barrier against oxygen and hydrogen, which inhibits the removal of oxygen from the oxide semiconductor layer surrounded by the insulating layers including an aluminum oxide film and the entry of impurities such as hydrogen in the oxide semiconductor layer. Thus, a highly purified intrinsic oxide semiconductor layer can be obtained. The threshold voltage is controlled effectively by gate electrode layers formed over and under the oxide semiconductor layer.

Provided is a semiconductor device which has low power consumption and can operate at high speed. The semiconductor device includes a memory element including a first transistor including crystalline silicon in a channel formation region, a capacitor for storing data of the memory element, and a second transistor which is a switching element for controlling supply, storage, and release of charge in the capacitor. The second transistor is provided over an insulating film covering the first transistor. The first and second transistors have a source electrode or a drain electrode in common.

A manufacturing method of a TFT substrate structure is provided, in which a graphene layer is formed on a semiconductor layer and after the formation of a second metal layer, the second metal layer is used as a shielding mask to conduct injection of fluoride ions into the graphene layer to form a modified area in a portion of the graphene layer that is located on and corresponds to a channel zone of the semiconductor layer. The modified area of the graphene layer shows a property of electrical insulation and a property of blocking moisture/oxygen so as to provide protection to the channel zone. Portions of the graphene layer that are located under source and drain electrodes are not doped with ions and preserve the excellent electrical conduction property of graphene to provide electrical connection between the source and drain electrodes and the semiconductor layer.