An approach for heat dissipation in integrated circuit devices is provided. A method includes forming an isolation layer on an electrically conductive feature of an integrated circuit device. The method also includes forming an electrically conductive layer on the isolation layer. The method additionally includes forming a plurality of nanowire structures on a surface of the electrically conductive layer.

Field-effect transistors (FETs) are described that comprise a semiconducting gate (SG) layer, referred to herein as SG-FETs. In one or more embodiments, the FETs can include a channel layer and a SG layer capacitively coupled to the channel layer. The SG layer has an embedded voltage-clamping function that provides internal gate over voltage protection without an additional protection circuit. The embedded voltage-clamping function is based on the SG layer having a maximum effective gate voltage that is clamped to the depletion threshold of the SG layer.

An approach for heat dissipation in integrated circuit devices is provided. A method includes forming an isolation layer on an electrically conductive feature of an integrated circuit device. The method also includes forming an electrically conductive layer on the isolation layer. The method additionally includes forming a plurality of nanowire structures on a surface of the electrically conductive layer.

The present invention relates to a semiconductor structure. The semiconductor structure comprises a semiconductor layer, at least one metallic carbon nanotube, and at least one graphene layer. The semiconductor layer defines a first surface and a second surface opposite to the first surface. The at least one metallic carbon nanotube is located on the first surface of the semiconductor layer. The at least one graphene layer is located on the second surface of the semiconductor layer. The at least one metallic carbon nanotube, the semiconductor layer and the at least one graphene layer are stacked with each other to form at least one three-layered stereoscopic structure. The present invention also relates a semiconductor device, and a photodetector.

An object of the present invention is to provide stable withstand voltage characteristics, reduce turn-off losses along with a reduction in leakage current when the device is off, improve controllability of turn-off operations, and improve blocking capability at turn-off. An N buffer layer includes a first buffer layer joined to an active layer and having one peak in impurity concentration, and a second buffer layer joined to the first buffer layer and an N.sup.− drift layer, having at least one peak point in impurity concentration, and having a lower maximum impurity concentration than the first buffer layer. The impurity concentration at the peak point of the first buffer layer is higher than the impurity concentration of the N.sup.− drift layer, and the impurity concentration of the second buffer layer is higher than the impurity concentration of the N.sup.− drift layer in the entire area of the second buffer layer.

Provided are two-dimensional material (2D)-based wiring conductive layer contact structures, electronic devices including the same, and methods of manufacturing the electronic devices. A 2D material-based field effect transistor includes a substrate; first to third 2D material layers on the substrate; an insulating layer on the first 2D material layer; a source electrode on the second 2D material layer; a drain electrode on the third 2D material layer; and a gate electrode on the insulating layer. The first 2D material layer is configured to exhibit semiconductor characteristics, and the second and third 2D material layers are metallic 2D material layers. The first 2D material layer may include a first channel layer of a 2D material and a second channel layer of a 2D material. The first 2D material layer may partially overlap the second and third 2D material layers.

A vertical metal oxide semiconductor field effect transistor (MOSFET) and a method for forming a vertical MOSFET is presented. The MOSFET comprises: a top contact; a bottom contact; a nanowire (602) forming a charge transport channel between the top contact and the bottom contact; and a wrap-around gate (650) enclosing the nanowire (602) circumference, the wrap-around gate (650) having an extension spanning over a portion of the nanowire (602) in a longitudinal direction of the nanowire (602), wherein the wrap-around gate (650) comprises a gate portion (614) and a field plate portion (616) for controlling a charge transport in the charge transport channel, and wherein the field plate portion (616) is arranged at a first radial distance (636) from the center of the nanowire (602) and the gate portion (614) is arranged at a second radial distance (634) from the center of the nanowire (602); characterized in that the first radial distance (636) is larger than the second radial distance (634).

Embodiments of the present invention provide a conductive substrate, a manufacturing method thereof and a display device. The conductive substrate includes a base substrate and a first conductive layer and a second conductive layer disposed on the base substrate, wherein the first conductive layer and the second conductive layer contact with each other, the first conductive layer is configured to be electrically connected with separated parts after the second conductive layer is fractured, and the first conductive layer includes a composite material layer or a nanowire conductive network layer.

Methods are provided to construct field-effect transistors comprising low-resistance metallic gate structures. A field-effect transistor includes a nanosheet stack and a metal gate which covers a gate region of the nanosheet stack. The nanosheet stack includes nanosheet channel layers and an etch stop layer disposed above an upper nanosheet channel layer. The metal gate includes a work function metal which encapsulates the nanosheet channel layers, and a gate electrode disposed above and in contact with the work function metal. An upper surface of the work function metal is recessed to be substantially coplanar with the etch stop layer. The gate electrode has a resistivity which is less than a resistivity of the work function metal. The etch stop layer protects the portion of the work function metal disposed between the etch stop layer and the upper nanosheet channel layer from being etched when recessing the work function metal.

Methods are provided to construct field-effect transistors comprising low-resistance metallic gate structures. A field-effect transistor includes a nanosheet stack and a metal gate which covers a gate region of the nanosheet stack. The nanosheet stack includes nanosheet channel layers and an etch stop layer disposed above an upper nanosheet channel layer. The metal gate includes a work function metal which encapsulates the nanosheet channel layers, and a gate electrode disposed above and in contact with the work function metal. An upper surface of the work function metal is recessed to be substantially coplanar with the etch stop layer. The gate electrode has a resistivity which is less than a resistivity of the work function metal. The etch stop layer protects the portion of the work function metal disposed between the etch stop layer and the upper nanosheet channel layer from being etched when recessing the work function metal.