An SRAM (static random access memory) includes a semiconductor substrate; a plurality of PD transistors, each including a first fin structure formed on the semiconductor substrate, a PD gate structure formed across the first fin structure and covering a portion of a top and sidewall surfaces of the first fin structure, and a first source/drain doped layer formed in the first fin structure on both sides of the PD gate structure; a plurality of adjacent transistors, each including a second fin structure formed on the semiconductor substrate and a second source/drain doped layer formed in the second fin structure; an isolation layer, formed on the semiconductor substrate; a fin sidewall film, formed on the isolation layer and covering sidewall surfaces of each PD gate structure; and a first PD dielectric layer, formed on the isolation layer and covering sidewall surfaces of the first source/drain doped layer.

A design method of a dummy pattern layout including the following steps is provided. An integrated circuit layout design including resistor elements is obtained via a computer. The locations of dummy conductive structures are configured, wherein the dummy conductive structures are aligned with the resistor elements. The locations of dummy support patterns are configured, wherein each of the dummy support patterns is configured between two adjacent dummy conductive structures, and each of the dummy conductive structures is equidistant from the dummy support patterns on both sides.

A semiconductor device includes a source region and a drain region of a first conductivity type, a body region of a second conductivity type between the source region and the drain region, a gate configured to control current through a channel of the body region, a drift zone of the first conductivity type between the body region and the drain region, a superjunction structure formed by a plurality of regions of the second conductivity type laterally spaced apart from one another by intervening regions of the drift zone, and a diffusion barrier structure disposed along sidewalls of the regions of the second conductivity type of the superjunction structure. The diffusion barrier structure includes alternating layers of Si and oxygen-doped Si and a Si capping layer on the alternating layers of Si and oxygen-doped Si.

A semiconductor device and a method of forming the same, the semiconductor device includes a substrate, a gate structure, a first dielectric layer, a second dielectric layer, a first plug and two metal lines. The substrate has a shallow trench isolation and an active area, and the gate structure is disposed on the substrate to cover a boundary between the active area and the shallow trench isolation. The first dielectric layer is disposed on the substrate, to cover the gate structure, and the first plug is disposed in the first dielectric layer to directly in contact with a conductive layer of the gate structure and the active area. The second dielectric layer is disposed on the first dielectric layer, with the first plug and the gate being entirely covered by the first dielectric layer and the second dielectric layer. The two metal lines are disposed in the second dielectric layer.

The application provides a SCR and a manufacturing method thereof. The SCR comprises: a P-type heavily doped region 20 and an N-type lightly doped region 28 forming an anode formed on the upper part of an N-type well 60, a P-type heavily doped region 26 and an N-type heavily doped region 24 forming a cathode formed on the upper part of a P-type well 70, an active region of the N-type well 60 is between the N-type lightly doped region 28 and an interface of the N-type well 60 and the P-type well 70, a STI is provided between the N-type heavily doped region 24 and the interface, the STI is adjacent to the N-type heavily doped region 24, and an active region of the P-type well 70 is provided between the STI and the interface. The present application can improve trigger voltage of the SCR and save layout area.

A semiconductor device includes a substrate, a first isolation structure, a second isolation structure and a dummy pattern. The substrate includes a first part surrounding a second part at a top view. The first isolation structure is disposed between the first part and the second part, to isolate the first part from the second part. The second isolation structure is disposed at at least one corner of the first part. The dummy pattern is disposed on the second isolation structure. The present invention also provides a method of forming said semiconductor device.

MEMS device formed in a semiconductor body which is monolithic and has a first and a second main surface. A buried cavity extends into the semiconductor body below and at a distance from the first main surface. A diaphragm extends between the buried cavity and the first main surface of the semiconductor body and has a buried face facing the buried cavity. A diaphragm insulating layer extends on the buried face of the diaphragm and a lateral insulating region extends into the semiconductor body along a closed line, between the first main surface and the diaphragm insulating layer, above the buried cavity. The lateral insulating region laterally delimits the diaphragm and forms, with the diaphragm insulating layer, a diaphragm insulating region which delimits the diaphragm and electrically insulates it from the rest of the wafer.

Released fins for advanced integrated circuit structure fabrication are described. For example, an integrated circuit structure includes a sub-fin. A dielectric spacer material is on the sub-fin. A fin is on the dielectric spacer material. A void in the dielectric spacer material, the void vertically between the sub-fin and the fin.

Integrated circuit structures having metal gates with tapered plugs, and methods of fabricating integrated circuit structures having metal gates with tapered plugs, are described. For example, includes a fin having a portion protruding above a shallow trench isolation (STI) structure. A gate dielectric material layer is over the protruding portion of the fin and over the STI structure. A conductive gate layer is over the gate dielectric material layer. A conductive gate fill material is over the conductive gate layer. A dielectric gate plug is laterally spaced apart from the fin. The dielectric gate plug is on the STI structure, and the dielectric gate plug has sides tapered outwardly from a top of the dielectric gate plug to a bottom of the dielectric gate plug.

A semiconductor device includes a substrate. The semiconductor device includes a dielectric fin that is formed over the substrate and extends along a first direction. The semiconductor device includes a gate isolation structure vertically disposed above the dielectric fin. The semiconductor device includes a gate structure extending along a second direction perpendicular to the first direction. The gate structure includes a first portion and a second portion separated by the gate isolation structure and the dielectric fin. The first portion of the gate structure presents a first beak profile and the second portion of the gate structure presents a second beak profile. The first and second beak profiles point toward each other.