A capacitor includes an electrode implemented in an electrode well of a substrate. The electrode well has a net N-type dopant concentration. The capacitor includes an electrode implemented in a conductive structure located above the substrate. The electrodes are separated by a dielectric layer located between the electrodes. A first tub region having a net P-type conductivity dopant concentration is located below and laterally surrounds the electrode well and a second tub region having a net N-type conductivity dopant concentration is located below and laterally surrounds the first tub region and the electrode well.

Various embodiments of the present application are directed towards an integrated circuit (IC) chip comprising a front-end-of-line (FEOL) through semiconductor-on-substrate via (TSV), as well as a method for forming the IC chip. In some embodiments, a semiconductor layer overlies a substrate. The semiconductor layer may, for example, be or comprise a group III-V semiconductor and/or some other suitable semiconductor(s). A semiconductor device is on the semiconductor layer, and a FEOL layer overlies the semiconductor device. The FEOL TSV extends through the FEOL layer and the semiconductor layer to the substrate at a periphery of the IC chip. An intermetal dielectric (IMD) layer overlies the FEOL TSV and the FEOL layer, and an alternating stack of wires and vias is in the IMD layer.

In some embodiments, the present disclosure relates to an integrated chip that includes a semiconductor device, a polysilicon isolation structure, and a first and second insulator liner. The semiconductor device is disposed on a frontside of a substrate. The polysilicon isolation structure continuously surrounds the semiconductor device and extends from the frontside of the substrate towards a backside of the substrate. The first insulator liner and second insulator liner respectively surround a first outermost sidewall and a second outermost sidewall of the polysilicon isolation structure. The substrate includes a monocrystalline facet arranged between the first and second insulator liners. A top of the monocrystalline facet is above bottommost surfaces of the polysilicon isolation structure, the first insulator liner, and the second insulator liner.

Various embodiments of the present application are directed towards an integrated circuit (IC) chip comprising a front-end-of-line (FEOL) through semiconductor-on-substrate via (TSV), as well as a method for forming the IC chip. In some embodiments, a semiconductor layer overlies a substrate. The semiconductor layer may, for example, be or comprise a group III-V semiconductor and/or some other suitable semiconductor(s). A semiconductor device is on the semiconductor layer, and a FEOL layer overlies the semiconductor device. The FEOL TSV extends through the FEOL layer and the semiconductor layer to the substrate at a periphery of the IC chip. An intermetal dielectric (IMD) layer overlies the FEOL TSV and the FEOL layer, and an alternating stack of wires and vias is in the IMD layer.

Methods for seam-less gapfill comprising sequentially depositing a film with a seam, reducing the height of the film to remove the seam and repeating until a seam-less film is formed. Some embodiments include optional film doping and film treatment (e.g., ion implantation and annealing).

In some embodiments, the present disclosure relates to an integrated chip that includes a semiconductor device, a polysilicon isolation structure, and a first and second insulator liner. The semiconductor device is disposed on a frontside of a substrate. The polysilicon isolation structure continuously surrounds the semiconductor device and extends from the frontside of the substrate towards a backside of the substrate. The first insulator liner and second insulator liner respectively surround a first outermost sidewall and a second outermost sidewall of the polysilicon isolation structure. The substrate includes a monocrystalline facet arranged between the first and second insulator liners. A top of the monocrystalline facet is above bottommost surfaces of the polysilicon isolation structure, the first insulator liner, and the second insulator liner.

A method for manufacturing a semiconductor device includes forming a plate structure over an isolation region. A drain electrode electrically connected to a drift region underlying the isolation region is formed, wherein the drain electrode is separated from a first location of the plate structure by a first distance along a central axis of an active area of the semiconductor device in a direction of a current flow between a source and a drain of the semiconductor device, the drain electrode is separated from a second location of the plate structure by a second distance along a line parallel to the central axis and within the active area. The first distance is less than the second distance.

A method for manufacturing an integrated circuit, includes providing a stack including a substrate and a dielectric layer disposed on the substrate, the substrate being formed from a semiconductor material having a resistivity greater than or equal to 500 Ω.cm, etching trenches extending through the dielectric layer and opening onto the substrate; etching the substrate isotropically and selectively with respect to the dielectric layer to form first cavities in the substrate; depositing a mobile electrical charge-trapping layer on the walls of the first cavities and on the side walls of the trenches so as to fill in the trenches in the dielectric layer, thus closing the first cavities in the substrate; and forming passive components vertically with respect to the first cavities.

An electronic device comprises a semiconductor substrate including majority carrier dopants of a first conductivity type, a semiconductor surface layer including majority carrier dopants of a second conductivity type, field oxide that extends on the semiconductor surface layer, and an isolation structure. The isolation structure includes a trench that extends through the semiconductor surface layer and into one of the semiconductor substrate and a buried layer of the semiconductor substrate, and polysilicon including majority carrier dopants of the second conductivity type, the polysilicon fills the trench to a side of the semiconductor surface layer.

Deep trench isolation structures for high voltage semiconductor-on-insulator devices are disclosed herein. An exemplary deep trench isolation structure surrounds an active region of a semiconductor-on-insulator substrate. The deep trench isolation structure includes a first insulator sidewall spacer, a second insulator sidewall spacer, and a multilayer silicon-comprising isolation structure disposed between the first insulator sidewall spacer and the second insulator sidewall spacer. The multilayer silicon-comprising isolation structure includes a top polysilicon portion disposed over a bottom silicon portion. The bottom polysilicon portion is formed by a selective deposition process, while the top polysilicon portion is formed by a non-selective deposition process. In some embodiments, the bottom silicon portion is doped with boron.