A display device includes a base substrate including a display area and a non-display area around the display area are defined, a first interlayer insulating layer disposed on the base substrate, a second interlayer insulating layer disposed on the first interlayer insulating layer, a first semiconductor layer disposed on the second interlayer insulating layer and including an oxide, and a first gate insulating layer disposed on the first semiconductor layer, wherein the material of the first interlayer insulating layer and the material of the second interlayer insulating layer are different from each other. Methods of manufacturing a display device are also disclosed.

Provided are a complementary carbon nanotube field effect transistor (CNT-FET) and a manufacturing method thereof. In particular, provided is carbon nanotube-based type conversion technology (p-type.fwdarw.n-type) using a photosensitive polyvinyl alcohol polymer which can be selectively cross-linked at a desired position based on a semiconductor standard process, i.e., photolithography. The CNT-FET includes: a substrate; a first channel layer formed on the substrate and made of a carbon nanotube; a first source electrode formed at one side of the first channel layer and made of a conductive material; a first drain electrode formed at the other side of the first channel layer and made of a conductive material; a conversion induction layer formed on the first channel layer between the first source electrode and the first drain electrode and configured to convert the first channel layer from a p-type to an n-type; a protective layer configured to protect the conversion induction layer; and a first gate electrode formed on the protective layer.

To suppress a malfunction of a circuit due to deterioration in a transistor. In a transistor which continuously outputs signals having certain levels (e.g., L-level signals) in a pixel or a circuit, the direction of current flowing through the transistor is changed (inverted). That is, by changing the level of voltage applied to a first terminal and a second terminal (terminals serving as a source and a drain) every given period, the source and the drain are switched every given period. Specifically, in a portion which successively outputs signals having certain levels (e.g., L-level signals) in a circuit including a transistor, L-level signals having a plurality of different potentials (L-level signals whose potentials are changed every given period) are used as the signals having certain levels.

To suppress a malfunction of a circuit due to deterioration in a transistor. In a transistor which continuously outputs signals having certain levels (e.g., L-level signals) in a pixel or a circuit, the direction of current flowing through the transistor is changed (inverted). That is, by changing the level of voltage applied to a first terminal and a second terminal (terminals serving as a source and a drain) every given period, the source and the drain are switched every given period. Specifically, in a portion which successively outputs signals having certain levels (e.g., L-level signals) in a circuit including a transistor, L-level signals having a plurality of different potentials (L-level signals whose potentials are changed every given period) are used as the signals having certain levels.

In a method of forming a gate-all-around field effect transistor (GAA FET), a bottom support layer is formed over a substrate and a first group of carbon nanotubes (CNTs) are disposed over the bottom support layer. A first support layer is formed over the first group of CNTs and the bottom support layer such that the first group of CNTs are embedded in the first support layer. A second group of carbon nanotubes (CNTs) are disposed over the first support layer. A second support layer is formed over the second group of CNTs and the first support layer such that the second group of CNTs are embedded in the second support layer. A fin structure is formed by patterning at least the first support layer and the second support layer.

A transistor comprises a channel region between a source region and a drain region, a dielectric material adjacent to the channel region, an electrode adjacent to the dielectric material, and an electrolyte between the dielectric material and the electrode. Related semiconductor devices comprising at least one transistors, related electronic systems, and related methods are also disclosed.

A dual-gate transistor and its production method are disclosed. An auxiliary gate is connected to the power supply of the integrated circuits, to form thick and high square-shaped potential barrier of minority carriers adjacent to the drain electrode, while the potential barrier is transparent for the majority carriers from the source electrodes. The potential barrier can effectively inhibit reverse minority carrier tunneling from the drain electrode at large drain-source voltage. The transistor can be easily turned on at small drain-source voltage, without significantly decreasing the on-state current. The dual-gate transistor can significantly suppress ambipolar behavior with increased current on/off ratio and reduced power consumption, and maintain the high performance. Based on transistors, strengthened CMOS circuits can have high noise margin, low voltage loss, reduced logic errors, high performance and low power consumption. Moreover, no additional power sources are added to the circuit, which makes it suitable for ultra-large-scale integrated circuits.

Provided are a foldable display panel, a manufacturing method thereof and a foldable display device. The foldable display panel is improved by replacing the conventional inorganic insulating layer with a bending resistant organic insulating layer to improve the bendability of the display panel; meanwhile, the cross-interconnected metal foil layer is added between the organic insulating layers to improve the resilience after bending, thereby improving the reliability of the product while improving the bending resistance of the display panel.

The present disclosure provides a manufacturing method of a thin film transistor, including: selecting a substrate, and forming a bottom gate, a gate insulating layer and a source-drain above the selected substrate, wherein the bottom gate and the source-drain adopts a conductive metal oxide with an adjustable work function as a metal conducting electrode; rinsing and drying the source-drain of the selected substrate, and ozone cleaning dried source-drain for a predetermined time under a predetermined illumination condition, bombarding the source-drain with oxygen plasma for a period of time, forming an active layer made of a carbon material over the source-drain; forming a passivation layer over the active layer. The implementation of the disclosure can reduce the contact resistance and improve the performance of the carbon-based thin film transistor device by adjusting the work function of the contact surface between the conductive metal and the active layer.

The present disclosure discloses a pixel circuit, a display apparatus and a dual-gate driving transistor. The pixel circuit comprises a dual-gate driving transistor having a drain electrically connected to a first power supply terminal; a threshold voltage compensation unit electrically connected to a data terminal, a first control terminal, a first gate of the dual-gate driving transistor, and a source of the dual-gate driving transistor respectively; a mobility compensation unit electrically connected to a sensing signal terminal, a second control terminal, and the source of the dual-gate driving transistor respectively; and a light emitting control unit electrically connected to the data terminal, a third control terminal, a second gate of the dual-gate driving transistor, the source of the dual-gate driving transistor, and a light emitting device respectively. The threshold voltage compensation unit and the mobility compensation unit perform threshold voltage compensation for the dual-gate driving transistor under the control of the data terminal, the first control terminal, the sensing signal terminal, and the second control terminal; and the mobility compensation unit and the light emitting control unit perform mobility compensation for the dual-gate driving transistor and control the dual-gate driving transistor to drive the light emitting device to emit light under the control of the sensing signal terminal, the second control terminal, the data terminal, and the third control terminal.