A semiconductor structure is disclosed. The semiconductor structure includes: a semiconductor substrate having a front surface and a back surface facing opposite to the front surface; a filling material extending from the front surface into the semiconductor substrate without penetrating through the semiconductor substrate, the filling material including an upper portion and a lower portion, the upper portion being in contact with the semiconductor substrate; and an epitaxial layer lined between the lower portion of the filling material and the semiconductor substrate. An associated manufacturing method is also disclosed.

Embodiments of the present disclosure relate to methods for forming a source/drain extension. In one embodiment, a method for forming an nMOS device includes forming a gate electrode and a gate spacer over a first portion of a semiconductor fin, removing a second portion of the semiconductor fin to expose a side wall and a bottom, forming a silicon arsenide (Si:As) layer on the side wall and the bottom, and forming a source/drain region on the Si:As layer. During the deposition of the Si:As layer and the formation of the source/drain region, the arsenic dopant diffuses from the Si:As layer into a third portion of the semiconductor fin located below the gate spacer, and the third portion becomes a doped source/drain extension region. By utilizing the Si:As layer, the doping of the source/drain extension region is controlled, leading to reduced contact resistance while reducing dopants diffusing into the channel region.

The present disclosure describes a semiconductor structure and a method for forming the same. The semiconductor structure can include a substrate, a fin structure over the substrate, a gate structure over the fin structure, an epitaxial region formed in the fin structure and adjacent to the gate structure. The epitaxial region can embed a plurality of clusters of dopants.

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.

A semiconductor device includes a substrate. The semiconductor device further includes a first polysilicon structure over the substrate, wherein the first polysilicon structure has a first grain size. The semiconductor device further includes a first barrier layer over the first polysilicon structure, wherein the first barrier layer has a non-uniform thickness. The semiconductor device further includes a second polysilicon structure over the first barrier layer, wherein the second polysilicon structure has a second grain size smaller than the first grain size.

A method of forming a power semiconductor device includes providing a semiconductor layer of a first conductivity type extending to a first side and having a first doping concentration of first dopants providing majority charge carriers of a first electric charge type in the layer, and forming a deep trench isolation including forming a trench which extends from the first side into the semiconductor layer and includes, in a vertical cross-section perpendicular to the first side, a wall, forming a compensation semiconductor region of the first conductivity type at the wall and having a second doping concentration of the first dopants higher than the first doping concentration, and filling the trench with a dielectric material. The amount of first dopants in the compensation semiconductor region is such that a field-effect of fixed charges of the first electric charge type which are trapped in the trench is at least partly compensated.

A fin field-effect transistor (“FinFET”) semiconductor device and method of forming the same. In one example, a semiconductor fin is formed over a semiconductor substrate. A conformal dielectric layer is formed on a top and side surfaces of the fin. A doped semiconductor layer is formed over the conformal dielectric layer, the doped semiconductor layer including a dopant. The doped semiconductor layer is heated thereby driving the dopant through the conformal dielectric layer and forming a doped region of the fin.

Disclosed herein are structures and techniques for device isolation in integrated circuit (IC) assemblies. In some embodiments, an IC assembly may include multiple transistors spaced apart by an isolation region. The isolation region may include a doped semiconductor body whose dopant concentration is greatest at one or more surfaces, or may include a material that is lattice-mismatched with material of the transistors, for example.

A diffuser includes a diffuser element made of silicon carbide having conductivity, conductive holding members for holding the diffuser element, conductive gaskets that seal between the diffuser element and the holding members. Static electricity on the diffuser element is eliminated through the gaskets, and the holding members.

A method comprising: forming an SiGe layer on sidewalls of one or more fins of a semiconductor device by a non-selective deposition of amorphous SiGe, the fins being formed of Si or SiGe; depositing a silicon oxide layer over the SiGe layer; and forming an SiGe channel formation region within each fin by performing Ge enrichment to diffuse Ge atoms from the SiGe layer into the one or more fins.