A semiconductor structure can include: a semiconductor substrate having a first region, a second region, and an isolation region disposed between the first region and the second region; an isolation component located in the isolation region; and where the isolation component is configured to recombine first carriers flowing from the first region toward the second region, and to extract second carriers flowing from the second region toward the first region.

A semiconductor device includes a semiconductor substrate comprising a P-type lightly doped semiconductor layer; an undoped silicon layer formed on the P-type lightly doped semiconductor layer; a first deep trench isolation and a second deep trench isolation formed from an upper surface of the semiconductor substrate to the undoped silicon layer and filled with insulating films; and a first N-type highly doped buried layer formed on the undoped silicon layer, and disposed between the first deep trench isolation and the second deep trench isolation, wherein the undoped silicon layer surrounds bottoms of the first and second deep trench isolations, and has a thickness greater than a thickness of the first N-type highly doped buried layer.

The embodiments of mechanisms for doping wells of finFET devices described in this disclosure utilize depositing doped films to dope well regions. The mechanisms enable maintaining low dopant concentration in the channel regions next to the doped well regions. As a result, transistor performance can be greatly improved. The mechanisms involve depositing doped films prior to forming isolation structures for transistors. The dopants in the doped films are used to dope the well regions near fins. The isolation structures are filled with a flowable dielectric material, which is converted to silicon oxide with the usage of microwave anneal. The microwave anneal enables conversion of the flowable dielectric material to silicon oxide without causing dopant diffusion. Additional well implants may be performed to form deep wells. Microwave anneal(s) may be used to anneal defects in the substrate and fins.

The present disclosure provides a method of manufacturing a semiconductor structure having an electrical contact. The method includes providing a semiconductor substrate; forming a dielectric structure over the semiconductor substrate, the dielectric structure having a trench; filling a polysilicon material in the trench of the dielectric structure; detecting the polysilicon material to determine a region of the polysilicon material having one or more defects formed therein; implanting the polysilicon material with a dopant material into the region; and annealing the polysilicon material to form a doped polysilicon contact.

An integrated circuit (IC) includes a semiconductor substrate in which a plurality of spaced-apart deep trench (DT) structures are formed. The IC further includes a plurality of DEEPN diffusion regions, each DEEPN diffusion region surrounding a corresponding one of the DT structures. Each of the DEEPN diffusion regions merges with at least one neighboring DEEPN diffusion region that surrounds at least one neighboring DT structure. The merged DEEPN diffusion regions may partially isolate two electronic devices, e.g. ESD devices.

A semiconductor device may include a first active component region (20) and a second active region (22) extending flat along a first lateral direction (L.sub.1) and a second lateral direction (L.sub.2) deviating from said first lateral direction. The semiconductor device may include a trench isolation structure (10, 10′) that electrically isolates the first active component region (20) from the second active region (22) along the first lateral direction (L.sub.1) and comprises at least one electrically conductive sidewall (14, 14′, 14″); said trench isolation structure (10) having a continuously extending insulating trench isolation base wall (30) and a plurality of spaced apart trench isolation portions (32a, 32b) with electrically conductive sidewall portions (14a, 14b) therebetween. The plurality of trench isolation portions (32a, 32b) and the electrically conductive sidewall portions (14a, 14b) are spaced (a, b) from the base wall (30).

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.

Before formation of gate insulating films, an oblique ion implantation of oxygen into opposing sidewalls of trenches, from a top of an oxide film mask is performed, forming oxygen ion-implanted layers in surface regions of the sidewalls. A peak position of oxygen concentration distribution of the oxygen ion-implanted layers is inside the oxide film mask. After removal of the oxide film mask, HTO films constituting the gate insulating films are formed. During deposition of the HTO films, excess carbon occurring at the start of the deposition of the HTO films and in the gate insulating films reacts with oxygen in the oxygen ion-implanted layers, thereby becoming an oxocarbon and being desorbed. The oxygen ion-implanted layers have a thickness in a direction orthogonal to the sidewalls at most half of the thickness of the gate insulating films, and an oxygen concentration higher than any other portion of the semiconductor substrate.

A semiconductor structure can include: a semiconductor substrate having a first region, a second region, and an isolation region disposed between the first region and the second region; an isolation component located in the isolation region; and where the isolation component is configured to recombine first carriers flowing from the first region toward the second region, and to extract second carriers flowing from the second region toward the first region.

A semiconductor structure formation method includes: providing a base and a trench located in the base, and depositing a fluidic initial film layer in the trench, impurity elements being present in the initial film layer; performing reactive oxygen treatment on the initial film layer; performing ultraviolet irradiation treatment on the initial film layer; and performing thermal treatment on the initial film layer in an aerobic environment, removing the impurity elements, and converting the initial film layer into a solid film layer. Quality of the film layer of the semiconductor structure can therefore be improved.