A semiconductor device is provided. The semiconductor device includes a first transistor on a first side of a shallow trench isolation (STI) region and a second transistor on a second side of the STI region. The first transistor includes a first conductive portion having a second conductivity type formed within a well having a first conductivity type, a first nanowire connected to the first conductive portion and a first active area, and a first gate surrounding the first nanowire. The second transistor includes a second conductive portion having the second conductivity type formed within the well, a second nanowire connected to the second conductive portion and a second active area, and a second gate surrounding the second nanowire. Excess current from an ESD event travels through the first conductive portion through the well to the second conductive portion bypassing the first nanowire and the second nanowire.

A method of fabricating a thin film transistor including following steps is provided. Sequentially form a semiconductor layer, a metal layer and an auxiliary layer on a substrate. Perform a crystallization process to transform the semiconductor layer into an active layer after the metal layer and the auxiliary layer are disposed on the semiconductor layer. After the active layer is formed, pattern the metal layer to form a source and a drain. Form a gate insulator and a gate. The gate insulator is disposed between the gate and the source and drain.

Embodiments of the invention provide a conductive structure, a thin film transistor, an array substrate, and a display device. The conductive structure comprises a copper layer formed of copper or copper alloy; a blocking layer for preventing copper ions of the copper layer from diffusing outward; and a diffusion prevention layer for preventing exterior ions from diffusing to the copper layer and disposed between the copper layer and the blocking layer. The multilayer conductive structure according to an embodiment of the invention can prevent exterior ions from diffusing into a copper layer and prevent copper ions from diffusing outward to reduce ions diffusion that adversely impacts the electricity performance and chemical corrosion resistance of the copper metal layer, and meanwhile can enhance adhesiveness of the conductive structure, which may be helpful for etching/patterning of the multilayer conductive structure.

The present invention provides a method for manufacturing an AMOLED backplane, in which after a first metal layer is patternized to form a first gate terminal (61), a second gate terminal (63), and an electrode plate (65), with the patternized first metal layer as a shielding layer, a patternized polysilicon layer is subjected to N-type light doping; and then, an insulation layer (7) is deposited and the insulation layer (7) is subjected to non-isotropic etching to form spacers (71), and with patternized first metal layer and the spacers (71) as a shielding layer, the patternized polysilicon layer is subjected to N-type heavy doping to form light-doping drain areas (N) exactly below the spacers (71) on the opposite sides of the first gate terminal (61), whereby light-doping drain areas (N) on opposite sides of a channel area of a switching TFT are made symmetric to each other and the length of the light-doping drain areas (N) is shorten; a conduction current is increased; a photoelectric current can be effectively reduced; one photo mask can be saved; and the cost can be lowered down.

Field-plate structures are disclosed for electrical field management in semiconductor devices. A field-plate semiconductor structure includes a semiconductor substrate, a source ohmic contact, a drain ohmic contact, and a gate contact disposed over a gate region between the source ohmic contact and the drain ohmic contact, and a source field plate connected to the source ohmic contact. A field-plate dielectric is disposed over the semiconductor substrate. An encapsulating dielectric is disposed over the gate contact, wherein the encapsulating dielectric covers a top surface of the gate contact. The source field plate is disposed over the field-plate dielectric in a field plate region, from which the encapsulating dielectric is absent.

As source and drain wiring, a base layer and a cap layer are each formed of a MoNiNb alloy film, and a low-resistance layer is formed of Cu. The resultant laminated metal film is patterned through one-time wet etching to form a drain electrode and a source electrode. Cu serving as a main wiring layer does not corrode because of being covered with a MoNiNb alloy having good corrosion resistance. Further, even when a protective insulating film including an oxide is formed by plasma CVD in an oxidizing atmosphere, Cu is not oxidized. With the wet etching, the sidewall taper angle of the laminated metal film can be controlled to 20 degrees or more and less than 70 degrees.

A method includes depositing a first metal layer on a native SiO.sub.2 layer that is disposed on at least one of a source and a drain of a metal-oxide-semiconductor field-effect transistor (MOSFET). A metal oxide layer is formed from the native SiO.sub.2 layer and the first metal layer, wherein the remaining first metal layer, the metal oxide layer, and the at least one of the source and the drain form a metal-insulator-semiconductor (MIS) contact.

A transparent conductive film includes a metal chalcogenide compound doped with a halogen and having a sheet resistance at room temperature of less than or equal to about 60 ohm/sq.

It is an object to manufacture a highly reliable display device using a thin film transistor having favorable electric characteristics and high reliability as a switching element. In a bottom gate thin film transistor including an amorphous oxide semiconductor, an oxide conductive layer having a crystal region is formed between an oxide semiconductor layer which has been dehydrated or dehydrogenated by heat treatment and each of a source electrode layer and a drain electrode layer which are formed using a metal material. Accordingly, contact resistance between the oxide semiconductor layer and each of the source electrode layer and the drain electrode layer can be reduced; thus, a thin film transistor having favorable electric characteristics and a highly reliable display device using the thin film transistor can be provided.

A high electron mobility transistor (HEMT) includes a substrate; and a first semiconductor layer over the substrate. The HEMT further includes a second semiconductor layer over the first semiconductor layer, wherein the second semiconductor layer has a band gap discontinuity with the first semiconductor layer, and at least one of the first semiconductor layer or the second semiconductor layer comprises indium. The HEMT further includes a top layer over the second semiconductor layer. The HEMT further includes a gate electrode over the top layer. The HEMT further includes a source and a drain on opposite sides of the gate electrode, wherein the top layer extends continuously from below the source, below the gate electrode, and to below the drain.