An integrated circuit device includes a first gate stack formed on a first high dielectric layer and comprising a first work function adjustment metal containing structure and a second gate stack formed on a second high dielectric layer and comprising a second work function adjustment metal containing structure having an oxygen content that is greater than that of the first work function adjustment metal containing structure.

A semiconductor device including at least one fin disposed on a surface of a semiconductor substrate is provided. The fin includes a main portion extending along a first direction, and at least one secondary portion extending outward from the main portion along a second direction not collinear with the first direction.

Transistors and methods of forming the same include forming a fin having an active layer between two sacrificial layers. A dummy gate is formed over the fin. Spacers are formed around the dummy gate. The dummy gate is etched away to form a gap over the fin. Material from the two sacrificial layers is etched away in the gap. A gate stack is formed around the active layer in the gap. Source and drain regions are formed in contact with the active layer.

Integrated chips and methods of forming the same include forming a gate stack around a first semiconductor fin and a second semiconductor fin. The gate stack around the second semiconductor fin is etched away. An extrinsic base is formed around the second semiconductor fin in a region exposed by etching away the gate stack.

Provided are liquid crystal display and the method for manufacturing the same. According to an aspect of the present invention, there is provided a liquid crystal display device, including a first substrate; a gate electrode disposed on the first substrate; a semiconductor pattern layer disposed on the gate electrode; and a source electrode and a drain electrode disposed on the semiconductor pattern layer and facing each other, wherein a diffusion prevention pattern is disposed on the semiconductor pattern layer to prevent diffusion into the semiconductor pattern layer or to maintain uniform thickness of the semiconductor pattern layer.

An object is to provide a semiconductor device having electrical characteristics such as high withstand voltage, low reverse saturation current, and high on-state current. In particular, an object is to provide a power diode and a rectifier which include non-linear elements. An embodiment of the present invention is a semiconductor device including a first electrode, a gate insulating layer covering the first electrode, an oxide semiconductor layer in contact with the gate insulating layer and overlapping with the first electrode, a pair of second electrodes covering end portions of the oxide semiconductor layer, an insulating layer covering the pair of second electrodes and the oxide semiconductor layer, and a third electrode in contact with the insulating layer and between the pair of second electrodes. The pair of second electrodes are in contact with end surfaces of the oxide semiconductor layer.

A semiconductor device and method of formation are provided. The semiconductor device includes a substrate, a first active area over the substrate, a second active area over the substrate, a graphene channel between the first active area and the second active area, and a first in-plane gate. In some embodiments, the graphene channel, the first in-plane gate, the first active area, and the second active area include graphene. A method of forming the first in-plane gate, the first active area, the second active area, and the graphene channel from a single layer of graphene is also provided.

A method of forming a finFET transistor device includes forming a crystalline, compressive strained silicon germanium (cSiGe) layer over a substrate; masking a first region of the cSiGe layer so as to expose a second region of the cSiGe layer; subjecting the exposed second region of the cSiGe layer to an implant process so as to amorphize a bottom portion thereof and transform the cSiGe layer in the second region to a relaxed SiGe (rSiGe) layer; performing an annealing process so as to recrystallize the rSiGe layer; epitaxially growing a tensile strained silicon layer on the rSiGe layer; and patterning fin structures in the tensile strained silicon layer and in the first region of the cSiGe layer.

Devices and methods of fabricating integrated circuit devices for increasing performance through gate cut last processes are provided. One method includes, for instance: obtaining an intermediate semiconductor device having a substrate including a plurality of fins, an STI layer, an oxide layer, and a gate material over the oxide layer, the fins extending into the gate material; removing the gate material and the oxide layer; depositing a high k material on a top surface of the STI layer, surrounding the fins; depositing a gate stack over the high k material; filling the top of the device with a gate contact metal; etching a portion of the gate contact metal, the metal gate stack, and the high k material; and filling the portion with an inter-layer dielectric. Also disclosed is an intermediate device formed by the method.

Disclosed herein is a technology for fabricating a nanowire field-effect sensor, in which a bulk silicon substrate is used so that the fabrication cost of the sensor can be reduced while the integration density of the sensor can be increased. In addition, the nanowire field-effect sensor includes a nano-network having a network structure in which pins are vertically arranged on the sidewalls of the network, respectively, and a gate insulating layer is applied to the pins. Due to this nano-network, the detection area of the sensor can be increased to increase its sensitivity, and the structural stability of the sensor can be ensured.