An organic thin film transistor, a manufacturing method thereof and an array substrate are provided. The manufacturing method of an organic thin film transistor includes: forming an organic semiconductor layer; partially sheltering the organic semiconductor layer, so that a sheltered region and an unsheltered region are formed on the organic semiconductor layer, the sheltered region corresponding to a region where an active layer of the organic thin film transistor needs to be formed; and doping the organic semiconductor layer, so that the organic semiconductor layer in correspondence with the sheltered region is not doped, and the organic semiconductor layer in correspondence with the unsheltered region is doped.

Embodiments of the invention include a method for fabricating a semiconductor device and the resulting structure. A substrate is provided. A plurality of metal portions are formed on the substrate, wherein the plurality of metal portions are arranged such that areas of the substrate remain exposed. A thin film layer is deposited on the plurality of metal portions and the exposed areas of the substrate. A dielectric layer is deposited, wherein the dielectric layer is in contact with portions of the thin film layer on the plurality of metal portions, and wherein the dielectric layer is not in contact with portions of the thin film layer on the exposed areas of the substrate such that one or more enclosed spaces are present between the thin film layer on the exposed areas of the substrate and the dielectric layer.

A flexible array substrate structure and manufacturing method thereof are disclosed, in which the patterning process of an organic semi-conductive layer is achieved by using the inside wall of the opening of a color film layer as a bank, so that one mask can be saved. Also, a process for manufacturing a device can be simplified by an improved device structure, so that the flexible array substrate structure of the invention can be obtained by only using four masks.

Provided are an organic electroluminescence device having high current efficiency and a long lifetime, and a biscarbazole derivative for realizing the device. The biscarbazole derivative has a specific substituent. The organic EL device has a plurality of organic thin-film layers including a light emitting layer between a cathode and an anode, and at least one layer of the organic thin-film layers contains the biscarbazole derivative.

Various embodiments provide a thin film transistor (TFT), a fabrication method thereof, and a display apparatus including the TFT. A carbon nanotube layer is formed over a substrate. The carbon nanotube layer includes a first plurality of carbon nanotubes. A plurality of gaps are formed through the carbon nanotube layer to provide a first patterned carbon nanotube layer. Carbon nanotube structures each including a second plurality of carbon nanotubes are formed in the plurality of gaps. The carbon nanotube structures have a carrier mobility different from the first patterned carbon nanotube layer, thereby forming an active layer for forming active structures of the thin-film transistor.

A multilayer graphene composite comprising a plurality of stacked graphene layers separated from one another by an ion gel, wherein the ion gel is intercalated between adjacent graphene layers such that ions within the ion gel are able to arrange themselves at the surfaces of the graphene layers to cause a detectable change in one or more of an electrical and optical property of the graphene layers when a gate voltage is applied to a gate electrode in proximity to the ion gel.

A method for making a metal oxide semiconductor carbon nanotube thin film transistor circuit. A p-type carbon nanotube thin film transistor and a n-type carbon nanotube thin film transistor are formed on an insulating substrate and stacked with each other. The p-type carbon nanotube thin film transistor includes a first semiconductor carbon nanotube layer, a first drain electrode, a first source electrode, a functional dielectric layer, and a first gate electrode. The n-type carbon nanotube thin film transistor includes a second semiconductor carbon nanotube layer, a second drain electrode, a second source electrode, a first insulating layer, and a second gate electrode. The first drain electrode and the second drain electrode are electrically connected with each other. The first gate electrode and the second gate electrode are electrically connected with each other.

A metal oxide semiconductor carbon nanotube thin film transistor circuit includes a p-type carbon nanotube thin film transistor and a n-type carbon nanotube thin film transistor stacked with each other. The p-type carbon nanotube thin film transistor includes a first semiconductor carbon nanotube layer, a first drain electrode, a first source electrode, a functional dielectric layer, and a first gate electrode. The n-type carbon nanotube thin film transistor includes a second semiconductor carbon nanotube layer, a second drain electrode, a second source electrode, a first insulating layer, and a second gate electrode. The first drain electrode and the second drain electrode are electrically connected with each other. The first gate electrode and the second gate electrode are electrically connected with each other.

The present invention relates to organic thin film transistors and the preparation and use thereof in sensing applications, and in particular in glucose sensing applications.

A method of making N-type semiconductor layer includes following steps. A semiconductor carbon nanotube layer is provided. A hafnium oxide layer is deposited on the semiconductor carbon nanotube layer via atomic layer deposition, wherein the atomic layer deposition includes following substeps. The semiconductor carbon nanotube layer is located into an atomic layer deposition system. The semiconductor carbon nanotube layer is heated to a temperature ranging from about 140° C. to about 200° C. A protective gas is continuously introduced into the atomic layer deposition system. The hafnium oxide layer is formed on the semiconductor carbon nanotube layer via introducing hafnium source and water vapor one by one into the atomic layer deposition system in a pulse manner.