A lateral double-diffused metal-oxide-semiconductor transistor includes a silicon semiconductor structure and a vertical gate. The vertical gate include a (a) gate conductor extending from a first outer surface of the silicon semiconductor structure into the silicon semiconductor structure and (b) a gate dielectric layer including a least three dielectric sections. Each of the at least three dielectric sections separates the gate conductor from the silicon semiconductor structure by a respective separation distance, where each of the respective separation distances is different from each other of the respective separation distances.

A face-down mountable chip-size package semiconductor device includes a semiconductor layer and N (N is an integer greater than or equal to three) vertical MOS transistors in the semiconductor layer. Each of the N vertical MOS transistors includes, on an upper surface of the semiconductor layer, a gate pad electrically connected to a gate electrode of the vertical MOS transistor and one or more source pads electrically connected to a source electrode of the vertical MOS transistor. The semiconductor layer includes a semiconductor substrate. The semiconductor substrate functions as a common drain region for the N vertical MOS transistors. For each of the N vertical MOS transistors, a surface area of the vertical MOS transistor in a plan view of the semiconductor layer increases with an increase in a maximum specified current of the vertical MOS transistor.

According to an embodiment of a semiconductor device, the semiconductor device includes: a first active cell area comprising a first plurality of parallel gate trenches; a second active cell area comprising a second plurality of parallel gate trenches; and a metallization layer above the first and the second active cell areas. The metallization layer includes: a first part contacting a semiconductor mesa region between the plurality of parallel gate trenches in the first and the second active cell areas; and a second part surrounding the first part. The second part of the metallization layer contacts the first plurality of gate trenches along a first direction and the second plurality of gate trenches along a second direction different from the first direction.

A method for fabricating a semiconductor device includes the steps of forming a metal gate on a substrate, a spacer around the metal gate, and a first interlayer dielectric (ILD) layer around the spacer, performing a plasma treatment process to transform the spacer into a first bottom portion and a first top portion, performing a cleaning process to remove the first top portion, and forming a second ILD layer on the metal gate and the first ILD layer.

A semiconductor device is disclosed. The semiconductor device may include a substrate including a first active pattern, the first active pattern vertically protruding from a top surface of the substrate, a first source/drain pattern filling a first recess, which is formed in an upper portion of the first active pattern, a first metal silicide layer on the first source/drain pattern, the first metal silicide layer including a first portion and a second portion, which are located on a first surface of the first source/drain pattern, and a first contact in contact with the second portion of the first metal silicide layer. A thickness of the first portion may be different from a thickness of the second portion.

A method of forming a semiconductor structure includes following steps. A first isolation is formed between a pair of active regions. A gate structure is formed on the first isolation structure. The active regions are etched to form recesses with curved top surfaces. The active regions are etched again to change each of the curved top surfaces to be a top surface and a sidewall substantially perpendicular to the top surface. A pair of contacts is formed respectively on the active regions, such that each of the contacts has a bottom surface and a sidewall substantially perpendicular to the bottom surface.

Disclosed is a semiconductor device comprising an active region that protrudes upwardly from a substrate, a plurality of channel patterns that are spaced apart from each other in a first direction on the active region, and a gate electrode that extends in the first direction on the active region and covers the plurality of channel patterns. Each of the plurality of channel patterns includes a plurality of semiconductor patterns that are spaced apart from each other in a direction perpendicular to a top surface of the active region. The gate electrode covers the top surface of the active region between the plurality of channel patterns.

A semiconductor device is provided. The semiconductor device includes a gate stack over a semiconductor substrate. The gate stack has a conductive structure and a gate dielectric layer, and a top of the gate dielectric layer is higher than a top of the conductive structure. The semiconductor device also includes a protection element over the gate stack. The semiconductor device further includes a spacer extending along a side surface of the protection element and a sidewall of the gate stack.

A Vertical Reconfigurable Field Effect Transistor (VRFET) has a substrate and a vertical channel. The vertical channel is in contact with a top silicide region that forms a lower Schottky junction with the vertical channel and a top silicide region that forms an upper Schottky junction with the vertical channel. The lower silicide region and the upper silicide region each form a source/drain (S/D) of the device. A lower gate stack surrounds the vertical channel and has a lower overlap that encompasses the lower Schottky junction. An upper gate stack surrounds the vertical channel and has an upper overlap that encompasses the upper Schottky junction. The lower gate stack is electrically insulated from the upper gate stack. The lower gate stack can electrically control the lower Schottky junction (S/D). The upper gate stack can electrically control the upper Schottky junction (S/D). The control of the lower Schottky junction (S/D) is independent and separate from the control of the upper Schottky junction (S/D). The upper gate stack is stacked above the lower gate stack enabling a reduced device footprint.

A transistor including at least one two-dimensional (2D) channel is disclosed. A transistor according to some example embodiments includes first to third electrodes separated from each other, and a channel layer that is in contact with the first and second electrodes, parallel to the third electrode, and includes at least one 2D channel. The at least one 2D channel includes at least two regions having different doping concentrations. A transistor according to some example embodiments includes: first to third electrodes separated from each other; a 2D channel layer that is in contact with the first and second electrodes and parallel to the third electrode; a first doping layer disposed under the 2D channel layer corresponding to the first electrode; and a second doping layer disposed under the 2D channel layer corresponding to the second electrode, wherein the first and second doping layers contact the 2D channel layer.