A semiconductor device including a FET includes an isolation insulating layer disposed in a trench of the substrate, a gate dielectric layer disposed over a channel region of the substrate, a gate electrode disposed over the gate dielectric layer, a source and a drain disposed adjacent to the channel region, and an embedded insulating layer disposed below the source, the drain and the gate electrode and both ends of the embedded insulating layer are connected to the isolation insulating layer.

A method for forming a semiconductor structure includes forming a gate structure on a substrate, performing a deposition process to form a nitride layer to cover the substrate and the gate structure, performing an in-situ annealing process to the nitride layer, and performing an anisotropic etching process to the nitride layer after the in-situ annealing process to form a spacer on a sidewall of the gate structure.

Methods for forming a semiconductor device structure are provided. The methods may include forming a molybdenum nitride film on a substrate by atomic layer deposition by contacting the substrate with a first vapor phase reactant comprising a molybdenum halide precursor, contacting the substrate with a second vapor phase reactant comprise a nitrogen precursor, and contacting the substrate with a third vapor phase reactant comprising a reducing precursor. The methods provided may also include forming a gate electrode structure comprising the molybdenum nitride film, the gate electrode structure having an effective work function greater than approximately 5.0 eV. Semiconductor device structures including molybdenum nitride films are also provided.

Device structures for a high-voltage semiconductor device and methods of forming such device structures. The structure comprises a semiconductor substrate and a layer stack including a first dielectric layer and a second dielectric layer. The first dielectric layer is positioned between the second dielectric layer and the semiconductor substrate. The structure further comprises a field-effect transistor including a first source/drain region in the semiconductor substrate, a second source/drain region in the semiconductor substrate, and a metal gate on the layer stack laterally between the first source/drain region and the second source/drain region. The second dielectric layer is positioned between the metal gate and the first dielectric layer. A contact extends through the layer stack to the first source/drain region.

Electronic device, comprising: a semiconductor body having a surface, an electrical conductivity P and a first doping value; at least one gate region on the surface; one or more source regions, having a second electrical conductivity N, extending in the semiconductor body at the surface and at a first side of the gate region; and at least one body contact region, of P+ type, extending in the semiconductor body at the surface and at the first side of the gate region 22. The first gate region has the shape of a stripe with main extension along a first direction. The first body contact region has a tapered shape along said first direction. The one or more source regions are adjacent to, and at least partially surround, the first body contact region.

A MOS transistor including a substrate, a conductive having lateral walls, drain and source regions, and spacers having an upper surface such that the spacers are buried in the substrate and are position between the conductive gate and the drain and source regions is provided. The spacers are each cuboid-shaped and have a width that is constant along the spacers height and independent from a height of the conductive gate. A device including the MOS transistor and a method of manufacture for producing a right-hand portion and a left-hand portion of a MOS transistor is also provided.

An ESD protection device includes an MOS transistor with a source region, drain region and gate region. A node designated for ESD protection is electrically coupled to the drain. A diode is coupled between the gate and source, wherein the diode would be reverse biased if the MOS transistor were in the active operating region.

In at least one embodiment, the method is designed for producing a light-emitting diode display (1). The method comprises the following steps: A) providing a growth substrate (2); B) applying a buffer layer (4) directly or indirectly onto a substrate surface (20); C) producing a plurality of separate growth points (45) on or at the buffer layer (4); D) producing individual radiation-active islands (5), originating from the growth points (45), wherein the islands (5) each comprise an inorganic semiconductor layer sequence (50) with at least one active zone (55) and have a mean diameter, when viewed from above onto the substrate surface (20), between 50 nm and 20 m inclusive; and E) connecting the islands (5) to transistors (6) for electrically controlling the islands (5).

The reliability of a semiconductor device is improved. In a manufacturing method, a film to be processed is formed over a circular semiconductor substrate, and a resist layer whose surface has a water-repellent property is formed thereover. Subsequently, the water-repellent property of the resist layer in the outer peripheral region of the circular semiconductor substrate is lowered by selectively performing first wafer edge exposure on the outer peripheral region of the semiconductor substrate, and then liquid immersion exposure is performed on the resist layer. Subsequently, second wafer edge exposure is performed on the outer peripheral region of the circular semiconductor substrate, and then the resist layer, on which the first wafer edge exposure, the liquid immersion exposure, and the second wafer edge exposure have been performed, is developed, so that the film to be processed is etched by using the developed resist layer.

A semiconductor transistor device includes a substrate having an active area and a trench isolation region surrounding the active area, a gate oxide layer, a gate, a spacer on a sidewall of the gate, a doping region on one side of the gate, an insulating cap layer covering the gate, the spacer and the doping region, and a redistributed contact layer (RCL) on the insulating cap layer. The RCL extends from the active area to the trench isolation region. A contact plug is disposed above the trench isolation region and is electrically connected to the gate or the doping region through the RCL.