A semiconductor device includes a first active region defined on a substrate, a first gate electrode across the first active region, a first drain region in the first active region at a position adjacent to the first gate electrode, an undercut region between the first active region and the first gate electrode, and a first gate spacer on a side surface of the first gate electrode and extending into the undercut region.

An IC may include an array of memory cells formed in a semiconductor, including memory cells arranged in rows and columns, each memory cell may include a floating body region defining at least a portion of a surface of the memory cell, the floating body region having a first conductivity type; a buried region located within the memory cell and located adjacent to the floating body region, wherein the buried region has a second conductivity type, wherein the floating body region is bounded on a first side by a first insulating region having a first thickness and on a second side by a second insulating region having a second thickness, and a gate region above the floating body region and the second insulating region and is insulated from the floating body region by an insulating layer; and control circuitry configured to provide electrical signals to said buried region.

An IC may include an array of memory cells formed in a semiconductor, including memory cells arranged in rows and columns, each memory cell may include a floating body region defining at least a portion of a surface of the memory cell, the floating body region having a first conductivity type; a buried region located within the memory cell and located adjacent to the floating body region, wherein the buried region has a second conductivity type, wherein the floating body region is bounded on a first side by a first insulating region having a first thickness and on a second side by a second insulating region having a second thickness, and a gate region above the floating body region and the second insulating region and is insulated from the floating body region by an insulating layer; and control circuitry configured to provide electrical signals to said buried region.

An array substrate, a manufacturing method thereof, and a display panel are provided. The array substrate includes at least one anti-radiation layer including a light incident side and a light-emitting side. The light-emitting side is positioned adjacent to an oxide semiconductor layer, the light incident side is configured to allow high energy light waves to enter the anti-radiation layer, the anti-radiation layer is configured to convert the high energy light waves into visible light, and the light-emitting side is configured to allow the visible light to enter the oxide semiconductor layer, thereby improving light stability of oxide semiconductors.

A semiconductor device including a substrate, a seed layer, a buffer layer, a channel layer, a barrier layer, a gate structure, a first source/drain structure, a second source/drain structure, and a contact is provided. The seed layer is disposed on the substrate. The buffer layer is disposed on the seed layer. The channel layer is disposed on the buffer layer. The barrier layer is disposed on the channel layer. The gate structure is disposed on the barrier layer. The first and second source/drain structures are disposed on opposite sides of the gate structure. The contact contacts the first source/drain structure. The distance between the gate structure and the contact is between 0.5 micrometers and 30 micrometers.

Disclosed herein are tunneling field effect transistors (TFETs), and related methods and computing devices. In some embodiments, a TFET may include: a first source/drain material having a p-type conductivity; a second source/drain material having an n-type conductivity; a channel material at least partially between the first source/drain material and the second source/drain material, wherein the channel material has a first side face and a second side face opposite the first side face; and a gate above the channel material, on the first side face, and on the second side face.

To provide a semiconductor device capable of reducing a parasitic capacitance, securing high reliability, and suppressing an increase in manufacturing cost. A semiconductor device is provided which includes a substrate including an embedded insulation film and a semiconductor layer on the embedded insulation film and on which a semiconductor element is formed and a gate electrode on the semiconductor layer, in which the gate electrode includes a band-shaped first electrode portion that extends from a center portion of the semiconductor layer and beyond an end of the semiconductor layer along a first direction in a case where the substrate is viewed from above, and in a cross section in a case where the first electrode portion and the substrate are cut along the first direction, a film thickness of the end of the semiconductor layer is thicker than a film thickness of the center portion of the semiconductor layer.

Disclosed herein are tunneling field effect transistors (TFETs), and related methods and computing devices. In some embodiments, a TFET may include: a first source/drain material having a p-type conductivity; a second source/drain material having an n-type conductivity; a channel material at least partially between the first source/drain material and the second source/drain material, wherein the channel material has a first side face and a second side face opposite the first side face; and a gate above the channel material, on the first side face, and on the second side face.

According to an aspect of the present inventive concept there is provided a field-effect transistor and a method for controlling such. The transistor comprises: a semiconductor layer; a source terminal, a drain terminal and a single gate.

The source and drain terminals are arranged on a first side of the semiconductor layer and the gate is arranged on a second side of the semiconductor layer opposite the first side.

The gate and the source terminal are arranged to overlap with a first common region of the semiconductor layer and the gate and the drain terminal are arranged to overlap with a second common region of the semiconductor layer.

The semiconductor layer further comprises a first gap region and a second gap region which the gate does not overlap.

The gate is configured to induce an electrostatic doping of the first and second common regions and induce a channel in a channel region of the semiconductor layer, extending between the first and second common regions.

The present invention discloses a stacked semiconductor chip structure and its process wherein the stacked semiconductor chip structure comprises a substrate as well as P-type semiconductor layers and N-type semiconductor layers which are stacked one by one on the substrate, wherein the P-type semiconductor layers and the N-type semiconductor layers are arranged alternately, there are at least two P-type semiconductor layers and at least two N-type semiconductor layers. The present invention uses the chemical vapor deposition method to stack and form the P-type semiconductor layers and the N-type semiconductor layers, uses the physical etching and the plasma cleaning to form the conducting layers and thus avoids using the photo masks, the photo resist and the mask aligners for the manufacture of semiconductor chips, reduces the complexity of semiconductor chip processes and increases the yield of semiconductor chip products.