An embodiment of the invention shows a high-voltage MOS field-effect transistor connected in series with a Schottky diode. When the Schottky diode is forwardly biased, the high-voltage MOSFET can act as a switch and sustain a high drain-to-source voltage. When the Schottky diode is reversely biased, the Schottky diode can protect the integrate circuit where the high-voltage MOSFET is formed, because the integrate circuit might otherwise burn out due to an exceedingly-large reverse current.

A lateral double-diffused metal-oxide-semiconductor field effect transistor includes a silicon semiconductor structure, first and second gate structures, and a trench dielectric layer. The first and second gate structures are disposed on the silicon semiconductor structure and separated from each other in a lateral direction. The trench dielectric layer is disposed in a trench in the silicon semiconductor structure and extends at least partially under each of the first and second gate structures in a thickness direction orthogonal to the lateral direction.

Semiconductor devices and methods of fabricating the semiconductor devices with cross coupled contacts using patterning for cross couple pick-up are disclosed. One method includes, for instance: obtaining an intermediate semiconductor device; performing a first lithography to pattern a first shape; performing a second lithography to pattern a second shape overlapping a portion of the first shape; processing the first shape and the second shape to form an isolation region at the overlap; and forming four regions separated by the isolation region. An intermediate semiconductor device is also disclosed.

A method for forming a film with an annealing step and a deposition step is disclosed. The method comprises an annealing step for inducing self-assembly or alignment within a polymer. The method also comprises a selective deposition step in order to enable selective deposition on a polymer.

A method of forming fine island patterns of semiconductor devices includes: forming a plurality of first mask pillars on a hard mask layer on a substrate; forming an upper buffer mask layer on the hard mask layer to cover the first mask pillars; patterning a plurality of islands in the upper buffer mask layer; separating each of the islands into a plurality of sub-islands; etching the upper buffer mask layer to form a plurality of second mask pillars on the hard mask layer; etching an exposed portion of the hard mask layer exposed by the first mask pillars and the second mask pillars until portions of the substrate are etched; and removing the first mask pillars, the second mask pillars, and remaining portions of the hard mask layer.

A lithography method is provided in accordance with some embodiments. The lithography method includes forming an under layer on a substrate; forming a silicon-containing middle layer on the under layer, wherein the silicon-containing middle layer has a thermal base generator (TBG) composite; forming a photosensitive layer on the silicon-containing middle layer; performing an exposing process to the photosensitive layer; and developing the photosensitive layer, thereby forming a patterned photosensitive layer.

A method for producing a semiconductor laser element includes providing a semiconductor wafer comprising: a nitride semiconductor substrate, and a semiconductor stack located on the substrate, the semiconductor stack including a plurality of nitride semiconductor layers; forming in the substrate a fissure starting point and a fissure extending from the fissure starting point; forming a cleavage reference portion extending parallel to a cleavage plane of the semiconductor wafer as estimated from a plan view shape of the fissure; and cleaving the semiconductor wafer parallel to the cleavage reference portion to thereby obtain resonator end faces.

After forming a sacrificial mandrel located over a substrate, alternating channel layer portions and sacrificial layer portions are formed on sidewalls of the sacrificial mandrel by epitaxial growth of alternating layers of a channel material and a sacrificial material followed by planarization. The sacrificial mandrel and the sacrificial layer portions are sequentially removed, leaving channel layer portions extending upwards from the substrate.

A method for manufacturing a memory device includes forming trenches in a substrate to define an active region, filling an insulation material in the trenches, treating at least one portion of the insulation material, removing an upper portion of the insulation material from the trenches, so as to expose upper portions of side surfaces of the active region and to convert remaining portions of the insulation material in the trenches to shallow trench isolation (STI) disposed on opposite sides of the active region, forming a lower oxide layer, a middle charge trapping layer, and an upper oxide layer which cover the exposed upper portions of the side surfaces of the active region, an upper surface of the active region between the side surfaces of the active region, and the STI, and forming a gate layer on the upper oxide layer.

A semiconductor device includes an interlayer insulating film formed on a substrate and including a trench, a gate insulating film formed in the trench, a work function adjusting film formed on the gate insulating film in the trench along sidewalls and a bottom surface of the trench, and including an inclined surface having an acute angle with respect to the sidewalls of the trench, and a metal gate pattern formed on the work function adjusting film in the trench to fill up the trench.