A system and method for providing electrical isolation between closely spaced devices in a high density integrated circuit (IC) are disclosed herein. An integrated circuit (IC) comprising a substrate, a first device, a second device, and a trench in the substrate and a method of fabricating the same are also discussed. The trench is self-aligned between the first and second devices and comprises a first filled portion and a second filled portion. The first fined portion of the trench comprises a dielectric material that forms a buried trench isolation for providing electrical isolation between the first and second devices. The self-aligned placement of the buried trench isolation allows for higher packing density without negatively affecting the operation of closely spaced devices in a high density IC.

A semiconductor structure includes an active region, an isolation structure, a first gate structure, and a second gate structure. The active region is disposed over a semiconductor substrate and has a first portion, a second portion, and a third portion. The third portion is between the first portion and the second portion. A shape of the first portion is different from a shape of the third portion, in a top view. The isolation structure is disposed over the semiconductor substrate and surrounds the active region. The first gate structure is disposed between the first portion and the third portion of the active region. The second gate structure is disposed between the second portion and the third portion of the active region.

The present disclosure describes a method that mitigates the formation of facets in source/drain silicon germanium (SiGe) epitaxial layers. The method includes forming an isolation region around a semiconductor layer and a gate structure partially over the semiconductor layer and the isolation region. Disposing first photoresist structures over the gate structure, a portion of the isolation region, and a portion of the semiconductor layer and doping, with germanium (Ge), exposed portions of the semiconductor layer and exposed portions of the isolation region to form Ge-doped regions that extend from the semiconductor layer to the isolation region. The method further includes disposing second photoresist structures over the isolation region and etching exposed Ge-doped regions in the semiconductor layer to form openings, where the openings include at least one common sidewall with the Ge-doped regions in the isolation region. Finally the method includes growing a SiGe epitaxial stack in the openings.

Semiconductor structures with electrical isolation and methods of forming a semiconductor structure with electrical isolation. A shallow trench isolation region, which contains a dielectric material, is positioned in a semiconductor substrate. A trench extendes through the shallow trench isolation region and to a trench bottom in the semiconductor substrate beneath the shallow trench isolation region. A dielectric layer at least partially fills the trench. A polycrystalline region, which is arranged in the semiconductor substrate, includes a portion that is positioned beneath the trench bottom.

A multi-voltage domain device includes a semiconductor layer including a first main surface, a second main surface arranged opposite to the first main surface, a first region including first circuity that operates in a first voltage domain, a second region including second circuity that operates in a second voltage domain different than the first voltage domain, and an isolation region that electrically isolates the first region from the second region in a lateral direction that extends parallel to the first and the second main surfaces. The isolation region includes at least one deep trench isolation barrier, each of which extends vertically from the first main surface to the second main surface. The multi-voltage domain device further includes at least one first capacitor configured to generate an electric field laterally across the isolation region between the first region and the second region.

An electronic chip including: a plurality of first semiconductor bars of a first conductivity type and of second semiconductor bars of a second conductivity type arranged alternately and contiguously on a region of the first conductivity type; two detection contacts arranged at the ends of each second bar; a circuit for detecting the resistance between the detection contacts of each second bar; insulating trenches extending in the second bars down to a first depth between circuit elements; and insulating walls extending across the entire width of each second bar down to a second depth greater than the first depth.

A first silicon oxide film is formed on the inner wall of a deep trench by oxidizing the inner wall of the deep trench while heating the inner wall. Then, a second silicon oxide film is formed using at least one of atmospheric pressure CVD and plasma CVD so that the second silicon oxide film covers the first silicon oxide film in the deep trench.

A method includes performing a plasma treatment on a first surface of a first material and a second surface of a second material simultaneously, wherein the first material is different from the second material. A third material is formed on treated first surface of the first material and on treated second surface of the second material. The first, the second, and the third materials may include a hard mask, a semiconductor material, and an oxide, respectively.

A technique disclosed herein improves a voltage resistance of an insulated gate type semiconductor device. A provided method is a method for manufacturing an insulated gate type switching device configured to switch between a front surface electrode and a rear surface electrode. The method includes implanting a first kind of second conductivity type impurities to bottom surfaces of gate trenches and diffusing the implanted first kind of second conductivity type impurities, and implanting a second kind of second conductivity type impurities to the bottom surfaces of the circumferential trenches and diffusing the implanted second kind of second conductivity type impurities.

A method of manufacturing a reverse-blocking IGBT (insulated gate bipolar transistor) includes forming a plurality of IGBT cells in a device region of a semiconductor substrate, forming a reverse-blocking edge termination structure in a periphery region of the semiconductor substrate which surrounds the device region, etching one or more trenches in the periphery region between the reverse-blocking edge termination structure and a kerf region of the semiconductor substrate, depositing a p-type dopant source which at least partly fills the one or more trenches and diffusing p-type dopants from the p-type dopant source into semiconductor material surrounding the one or more trenches, so as to form a continuous p-type doped region in the periphery region which extends from a top surface of the semiconductor substrate to a bottom surface of the semiconductor substrate after thinning of the semiconductor substrate at the bottom surface.