A semiconductor device includes a semiconductor-on-insulator substrate having an insulator layer, and at least one silicon germanium (SiGe) fin having a superlattice structure. The SiGe fin is formed on an upper surface of the insulator layer. A gate stack is formed on an upper surface of the at least one silicon germanium fin. The gate stack includes first and second opposing spacers defining a gate length therebetween. First and second epitaxial source/drain structures are formed on the insulator layer. The first and second epitaxial source/drain structures extend beneath the spacer to define a silicon germanium gate channel beneath the gate stack.

A method for forming MOS transistor includes providing a substrate including a semiconductor surface having a gate electrode on a gate dielectric thereon, dielectric spacers on sidewalls of the gate electrode, a source and drain in the semiconductor surface on opposing sides of the gate electrode, and a pre-metal dielectric (PMD) layer over the gate electrode and over the source and drain regions. Contact holes are formed through the PMD layer to form a contact to the gate electrode and contacts to the source and drain. A post contact etch dielectric layer is then deposited on the contacts to source and drain and on sidewalls of the PMD layer. The post contact etch dielectric layer is selectively removed from the contacts to leave a dielectric liner on sidewalls of the PMD layer. A metal silicide layer is formed on the contacts to the source and drain.

A method of forming two or more nano-sheet devices with varying electrical gate lengths, including, forming at least two cut-stacks including a plurality of sacrificial release layers and at least one alternating nano-sheet channel layer on a substrate, removing a portion of the plurality of sacrificial release layers to form indentations having an indentation depth in the plurality of sacrificial release layers, and removing a portion of the at least one alternating nano-sheet channel layer to form a recess having a recess depth in the at least one alternating nano-sheet channel layers, where the recess depth is greater than the indentation depth.

A material layer, a semiconductor device including the material layer, and methods of forming the material layer and the semiconductor device are provided herein. A method of forming a SiOCN material layer may include supplying a silicon source onto a substrate, supplying a carbon source onto the substrate, supplying an oxygen source onto the substrate, supplying a nitrogen source onto the substrate, and supplying hydrogen onto the substrate. When a material layer is formed according to a method of the present inventive concepts, a material layer having a high tolerance to wet etching and/or good electric characteristics may be formed, and may even be formed when the method is performed at a low temperature.

A semiconductor device includes a gate structure disposed over a substrate, and sidewall spacers disposed on both side walls of the gate structure. The sidewall spacers includes at least four spacer layers including first to fourth spacer layers stacked in this order from the gate structure.

A semiconductor chip has a semiconductor body with a bottom side and a top side arranged distant from the bottom side in a vertical direction, an active and a non-active transistor region, a drift region formed in the semiconductor body, a contact terminal for externally contacting the semiconductor chip, and a plurality of transistor cells formed in the semiconductor body. Each of the transistor cells has a first electrode. Each of a plurality of connection lines electrically connects another one of the first electrodes to the contact terminal pad at a connecting location of the respective connection line. Each of the connection lines includes a resistance section formed of a locally increased specific resistance relative to a specific resistance of adjacent semiconductor material or metal of the respective connection line. Each of the connecting locations and each of the resistance sections is arranged in the non-active transistor region.

A semiconductor device includes a gate structure disposed over a substrate, and sidewall spacers disposed on both side walls of the gate structure. The sidewall spacers includes at least four spacer layers including first to fourth spacer layers stacked in this order from the gate structure.

Semiconductor device having less defects in a gate insulating film and improved reliability and methods of forming the semiconductor devices are provided. The semiconductor devices may include a gate insulating film on a substrate and a gate electrode structure on the gate insulating film. The gate electrode structure may include a lower conductive film, a silicon oxide film, and an upper conductive film sequentially stacked on the gate insulating film. The lower conductive film may include a barrier metal layer.

A semiconductor device and a method for producing thereof is provided. The semiconductor device includes a plurality of device cells, each comprising a body region, a source region, and a gate electrode adjacent to the body region and dielectrically insulated from the body region by a gate dielectric; and an electrically conductive gate layer comprising the gate electrodes or electrically connected to the gate electrodes of the plurality of device cells. The gate layer is electrically connected to a gate conductor and includes at least one of an increased resistance region and a decreased resistance region.

A semiconductor device includes a substrate including a trench; a gate dielectric layer formed over a surface of the trench; a gate electrode positioned in the trench at a level lower than a top surface of the substrate, and including a first buried portion and a second buried portion over the first buried portion; and a first doping region and a second doping region formed in the substrate on both sides of the gate electrode, and overlapping with the second buried portion, wherein the first buried portion includes a first barrier which has a first work function, and the second buried portion includes a second barrier which has a second work function lower than the first work function.