A field effect transistor comprising a substrate, at least one gate stack structure, source and drain regions and an interconnect structure is described. The interconnect structure comprises a metal interconnect connected to a conductive region, an adhesion sheath structure and a cap layer. The adhesion sheath structure is disposed between the metal interconnect and inter-dielectric layers and surrounds the metal interconnect. The cap layer is disposed on the metal interconnect and covers a gap between the metal interconnect and the inter-dielectric layer.

A power semiconductor package that includes a semiconductor die having at least two power electrodes and a conductive clip electrically and mechanically coupled to each power electrode.

A method of manufacturing a nanowire device is disclosed. The method includes providing a substrate, wherein the substrate comprises a pair of support pads, a recess disposed between the support pads, a second insulating layer disposed on the support pads, a third insulating layer disposed on a bottom of the recess, and at least one nanowire suspended between the support pads at a top portion of the recess; forming a first insulating layer on the nanowire; depositing a dummy gate material over the substrate on the first insulating layer, and patterning the dummy gate material to form a dummy gate structure surrounding a channel region; forming a first oxide layer on laterally opposite sidewalls of the dummy gate; and extending the nanowire on laterally opposite ends of the channel region to the respective support pads, so as to form a source region and a drain region.

A semiconductor device has an FET of a trench-gate structure obtained by disposing a conductive layer, which will be a gate, in a trench extended in the main surface of a semiconductor substrate, wherein the upper surface of the trench-gate conductive layer is formed equal to or higher than the main surface of the semiconductor substrate. The conductive layer of the trench gate is formed to have a substantially flat or concave upper surface and the upper surface is formed equal to or higher than the main surface of the semiconductor substrate. After etching of the semiconductor substrate to form the upper surface of the conductive layer of the trench gate, a channel region and a source region are formed by ion implantation so that the semiconductor device is free from occurrence of a source offset.

A method of forming a semiconductor structure includes forming a gate structure having a first conductive material above a semiconductor substrate, gate spacers on opposing sides of the first conductive material, and a first interlevel dielectric (ILD) layer surrounding the gate spacers and the first conductive material. An upper portion of the first conductive material is recessed. The gate spacers are recessed until a height of the gate spacers is less than a height of the gate structure. An isolation liner is deposited above the gate spacers and the first conductive material. A portion of the isolation liner is removed so that a top surface of the first conductive material is exposed. A second conductive material is deposited in a contact hole created above the first conductive material and the gate spacers to form a gate contact.

Structures and formation methods of a semiconductor device structure are provided. The semiconductor device structure includes a gate stack over a semiconductor substrate and a protection element over the gate stack. A top of the protection element is wider than a bottom of the protection element. The semiconductor device structure also includes a spacer element over a side surface of the protection element and a sidewall of the gate stack. The semiconductor device structure further includes a conductive contact electrically connected to a conductive feature over the semiconductor substrate.

A semiconductor device and a method of fabricating the same include a semiconductor substrate, a high-k dielectric pattern and a metal-containing pattern sequentially being stacked on the semiconductor substrate, a gate pattern including poly semiconductor and disposed on the metal-containing pattern, and a protective layer disposed on the gate pattern, wherein the protective layer includes oxide, nitride and/or oxynitride of the poly semiconductor.

A semiconductor device includes a gate stack overlying a substrate. The semiconductor device further includes a spacer on sidewalls of the gate stack, where a top surface of the spacer is above a top surface of the gate stack. Additionally, the semiconductor device includes a protection layer overlying the gate stack and filling at least a portion of a space surrounded by the spacer above the top surface of the gate stack. Furthermore, the semiconductor device includes a contact hole over the spacer, where the contact hole extends over the gate stack, and where a sidewall of the contact hole has a step-wise shape.

An electronic device includes a transistor. The transistor includes a body including a metal oxide; a gate electrode; and a gate insulating layer interposed between the body and the gate electrode, wherein the transistor is turned on or turned off by movement of oxygen vacancies in the body according to voltages applied to the gate electrode and the body.

The present invention provides a high-voltage metal-oxide-semiconductor transistor device and a manufacturing method thereof. First, a semiconductor substrate is provided and a dielectric layer and a conductive layer sequentially stacked on the semiconductor substrate. Then, the conductive layer is patterned to form a gate and a dummy gate disposed at a first side of the gate and followed by forming a first spacer between the gate and the dummy gate and a second spacer at a second side of the gate opposite to the first side, wherein the first spacer includes an indentation. Subsequently, the dummy gate is removed.