To provide an oxide semiconductor with a novel structure. Such an oxide semiconductor is composed of an aggregation of a plurality of InGaZnO.sub.4 crystals each of which is larger than or equal to 1 nm and smaller than or equal to 3 nm, and in the oxide semiconductor, the plurality of InGaZnO.sub.4 crystals have no orientation. Alternatively, such an oxide semiconductor is such that a diffraction pattern like a halo pattern is observed by electron diffraction measurement performed by using an electron beam with a probe diameter larger than or equal to 300 nm, and that a diffraction pattern having a plurality of spots arranged circularly is observed by electron diffraction measurement performed by using an electron beam with a probe diameter larger than or equal to 1 nm and smaller than or equal to 30 nm.

The present invention provides a semiconductor crystal comprising a semiconductor material having a tuned band gap energy, and methods for preparation thereof. More particularly, the invention provides a semiconductor crystal comprising a semiconductor material and amino acid molecules, peptides, or a combination thereof, incorporated within the crystal lattice, wherein the amino acid molecules, peptides, or combination thereof tune the band gap energy of the semiconductor material.

The present invention provides a TFT arrangement structure, comprising a first thin film transistor (T1) and a second thin film transistor (T2) controlled by the same control signal line; the first active layer (SC1) of the first thin film transistor (T1) and the second active layer (SC2) of the second thin film transistor (T2) are at different layers, and positioned to stack up in space, and the first source (S1) and the first drain (D1) of the first thin film transistor (T1) contact the first active layer (SC1), and the second source (S2) and the second drain (D2) of the second thin film transistor (T2) contact the second active layer (SC2); the bottom gate layer (Bottom Gate) of the first thin film transistor (T1) is positioned under the first active layer (SC1), and the top gate layer (Top Gate) of the second thin film transistor (T2) is above the second active layer (SC2). The TFT arrangement structure can reduce the space of the circuit arrangement to increase the flexibility of the circuit arrangement and satisfy the demands of the narrow frame and high resolution to the display panel.

The present invention provides a TFT arrangement structure, comprising a first thin film transistor (T1) and a second thin film transistor (T2) controlled by the same control signal line; the first active layer (SC1) of the first thin film transistor (T1) and the second active layer (SC2) of the second thin film transistor (T2) are at different layers, and positioned to stack up in space, and the first source (S1) and the first drain (D1) of the first thin film transistor (T1) contact the first active layer (SC1), and the second source (S2) and the second drain (D2) of the second thin film transistor (T2) contact the second active layer (SC2); the bottom gate layer (Bottom Gate) of the first thin film transistor (T1) is positioned under the first active layer (SC1), and the top gate layer (Top Gate) of the second thin film transistor (T2) is above the second active layer (SC2). The TFT arrangement structure can reduce the space of the circuit arrangement to increase the flexibility of the circuit arrangement and satisfy the demands of the narrow frame and high resolution to the display panel.

According to one embodiment, a transparent conductor includes a transparent substrate; a metal nanowire layer disposed on the transparent substrate and including a plurality of metal nanowires; a graphene oxide layer covering the metal nanowire layer; and an electrical insulating resin layer disposed in contact with the graphene oxide layer.

A semiconductor device includes a monocrystalline substrate configured to form a channel region between two recesses in the substrate. A gate conductor is formed on a passivation layer over the channel region. Dielectric pads are formed in a bottom of the recesses and configured to prevent leakage to the substrate. Source and drain regions are formed in the recesses on the dielectric pads from a deposited non-crystalline n-type material with the source and drain regions making contact with the channel region.

A semiconductor device includes a monocrystalline substrate configured to form a channel region between two recesses in the substrate. A gate conductor is formed on a passivation layer over the channel region. Dielectric pads are formed in a bottom of the recesses and configured to prevent leakage to the substrate. Source and drain regions are formed in the recesses on the dielectric pads from a deposited non-crystalline n-type material with the source and drain regions making contact with the channel region.

The film structure according to an embodiment of the present invention includes at least one active monolayer having an energy level quantized in at least one axial direction and at least one barrier alternately stacked with the at least one active monolayer. Current flows through the active monolayer, and the current flow may be limited by the quantized energy level.

Memory devices and electronic systems include an array of vertical memory cells positioned along respective vertical channels to define vertical memory strings. Each of the vertical channels includes a channel material exhibiting an electron mobility of at least about 30 cm.sup.2/(V.Math.s) and a room temperature band gap of at least about 1.40 eV (e.g., zinc oxide, silicon carbide, indium phosphide, indium gallium zinc oxide, gallium arsenide, or molybdenum disulfide) and a bottom plug material exhibiting a room temperature band gap of less than about 1.10 eV (e.g., silicon germanium, germanium, or indium gallium arsenide). Methods of fabricating a memory device include forming such a bottom plug material within vertical channels and forming such a channel material electrically coupled to the bottom plug material.

Memory devices and electronic systems include an array of vertical memory cells positioned along respective vertical channels to define vertical memory strings. Each of the vertical channels includes a channel material exhibiting an electron mobility of at least about 30 cm.sup.2/(V.Math.s) and a room temperature band gap of at least about 1.40 eV (e.g., zinc oxide, silicon carbide, indium phosphide, indium gallium zinc oxide, gallium arsenide, or molybdenum disulfide) and a bottom plug material exhibiting a room temperature band gap of less than about 1.10 eV (e.g., silicon germanium, germanium, or indium gallium arsenide). Methods of fabricating a memory device include forming such a bottom plug material within vertical channels and forming such a channel material electrically coupled to the bottom plug material.