An object is to provide a technique that suppresses decrease in the breakdown voltage of a protective element. There is provided a semiconductor device that comprises a vertical MOS transistor and a protective element. A first nitride semiconductor layer has a convex that is protruded toward a second nitride semiconductor layer. The convex has a top face placed at a position to overlap with at least part of an ohmic electrode of a second conductive type when viewed from a stacking direction of a stacked body. The thickness of the second nitride semiconductor layer in a portion which a bottom face of a trench is in contact with is greater than the thickness of the second nitride semiconductor layer in a portion which the top face of the convex is in contact with.

According to one embodiment, a semiconductor device includes a plurality of first semiconductor regions of a first conductivity type, a plurality of second semiconductor regions of a second conductivity type, a third semiconductor region of the second conductivity type, a fourth semiconductor region of the second conductivity type, a fifth semiconductor region of the first conductivity type, and a gate electrode. An impurity concentration of the second conductivity type of the third semiconductor region is higher than an impurity concentration of the second conductivity type of the second semiconductor regions. The fourth semiconductor region is provided on the first semiconductor regions. The gate electrode provided on the fourth semiconductor region with a gate insulation layer interposed. The gate electrode extends in a third direction. The third direction intersects the first direction. The third direction is parallel to a plane including the first direction and the second direction.

A system for object reconstruction includes an illuminating unit, comprising a coherent light source and a generator of a non-periodic pattern. A diffractive optical element (DOE) is disposed in an optical path of illuminating light propagating from the illuminating unit toward an object, thereby projecting the non-periodic pattern onto an object. An imaging unit detects a light response of an illuminated region and generating image data indicative of the object within the projected pattern. A processor reconstructs a three-dimensional (3D) map of the object responsively to a shift of the pattern in the image data relative to a reference image of the pattern.

Methods for forming a fin-based RF diode with improved performance characteristics and the resulting devices are disclosed. Embodiments include forming fins over a substrate, separated from each other, each fin having a lower portion and an upper portion; forming STI regions over the substrate, between the lower portions of adjacent fins; implanting the lower portion of each fin with a first-type dopant; implanting the upper portion of each fin, above the STI region, with the first-type dopant; forming a junction region around a depletion region and along exposed sidewalls and a top surface of the upper portion of each fin; and forming a contact on exposed sidewalls and a top surface of each junction region.

A method is provided for fabricating a buried-channel MOSFET and a surface-channel MOSFET of the same type and different gate electrodes on a same wafer. The method includes providing a semiconductor substrate having a well area and a plurality of shallow trench isolation structures; forming a threshold implantation region doped with impurity ions opposite of that of the well area in the well area for the buried-channel MOSFET; forming a gate structure including a gate dielectric layer and a gate electrode on the semiconductor substrate, wherein the gate electrode of the buried-channel MOSFET is doped with impurity ions with a same type as that of the well area, and the gate electrode of the surface-channel MOSFET is doped with impurity ions with a type opposite of that of the well area; and forming source and drain regions in the semiconductor substrate at both sides of the gate structure.

A semiconductor structure includes a substrate, at least one active semiconductor fin, at least one insulating structure, a gate electrode, and a gate dielectric. The active semiconductor fin is disposed on the substrate. The insulating structure is disposed on the substrate and adjacent to the active semiconductor fin. A top surface of the insulating structure is non-concave and is lower than a top surface of the active semiconductor fin. The gate electrode is disposed over the active semiconductor fin. The gate dielectric is disposed between the gate electrode and the active semiconductor fin.

A power semiconductor device includes a first contact, a second contact, and a semiconductor volume disposed between the first contact and the second contact. The semiconductor volume includes an n-doped field stop layer configured to spatially delimit an electric field that in the semiconductor volume during operation of the power semiconductor device, a heavily p-doped zone and a neighboring heavily n-doped zone, which together form a tunnel diode. The tunnel diode is located in the vicinity of, or adjacent to, or within the field stop layer. The tunnel diode is configured to provide protection against damage to the device due to a rise of an electron flow in an abnormal operating condition, by the fast provision of holes. Further, a method for producing such devices is provided.

Components can be damaged if they are exposed to excess voltages. A device is disclosed herein which can be placed in series with a component and a node that may be exposed to high voltages. If the voltage becomes too high, the device can autonomously switch into a relatively high impedance state, thereby protecting the other components.

A semiconductor structure is provided, comprising a substrate (130), a support structure (131), a base region (100), a gate stack, a spacer (240), and a source/drain region, wherein the gate stack is located above the base region (100), and the base region (100) is supported above the substrate (130) by the support structure (131), wherein the support structure (131) has a sigma-shaped lateral cross-section; an isolation structure (123) is formed below edges on both sides of the base region (100), wherein a portion of the isolation structure (123) is connected to the substrate (130); a cavity (112) is formed between the isolation structure (123) and the support structure (131); and a source/drain region is formed on both sides of the base region (100) and the isolation structure (123). Accordingly, a method for manufacturing the semiconductor structure is also provided.

A semiconductor device includes a substrate, a gate structure, a sidewall spacer, and an epitaxial layer. The gate structure is disposed on the substrate, and the substrate has at least one recess disposed adjacent to the gate structure. The sidewall spacer is disposed on at least two sides of the gate structure. The sidewall spacer includes a first spacer layer and a second spacer layer, and the first spacer layer is disposed between the gate structure and the second spacer layer. The epitaxial layer is disposed in the recess, and the recess is a circular shaped recess. A distance between an upmost part of the recess and the gate structure is less than a width of the sidewall spacer.