A wide band gap semiconductor device includes a semiconductor layer, a trench formed in the semiconductor layer, first, second, and third regions having particular conductivity types and defining sides of the trench, and a first electrode embedded inside an insulating film in the trench. The second region integrally includes a first portion arranged closer to a first surface of the semiconductor layer than to a bottom surface of the trench, and a second portion projecting from the first portion toward a second surface of the semiconductor layer to a depth below a bottom surface of the trench. The second portion of the second region defines a boundary surface with the third region, the boundary region being at an incline with respect to the first surface of the semiconductor layer.

A semiconductor device includes a substrate, a fin structure and an isolation layer formed on the substrate and adjacent to the fin structure. The semiconductor device includes a gate structure formed on at least a portion of the fin structure and the isolation layer. The semiconductor device includes an epitaxial layer including a strained material that provides stress to a channel region of the fin structure. The epitaxial layer has a first region and a second region, in which the first region has a first doping concentration of a first doping agent and the second region has a second doping concentration of a second doping agent. The first doping concentration is greater than the second doping concentration. The epitaxial layer is doped by ion implantation using phosphorous dimer.

An LDMOS device and a fabrication method for fabricating the same are provided. The LDMOS device includes: a substrate, which is of a first dopant type; an epitaxial layer, which is of the first dopant type and formed on the substrate; a gate structure disposed on an upper surface of the epitaxial layer; a well region of the first dopant type and a drift region of a second dopant type, both disposed in the epitaxial layer; a source region of the second dopant type, disposed within the well region; a drain region of the first dopant type, disposed within the drift region; a first insulating layer covering an upper surface and two sidewalls of the gate structure and the upper surface of the epitaxial layer; and a first conducting channel extending through the first insulating layer, source region and epitaxial layer, in contact the source region.

Junction field effect transistors (JFETs) and related manufacturing methods are disclosed herein. A disclosed JFET includes a vertical channel region located in a mesa and a first channel control region located on a first side of the mesa. The first channel control region is at least one of a gate region and a first base region. The JEFT also includes a second base region located on a second side of the mesa and extending through the mesa to contact the vertical channel region. The vertical channel can be an implanted vertical channel. The vertical channel can be asymmetrically located in the mesa towards the first side of the mesa.

A channel stop and well dopant migration control implant (e.g., of argon) can be used in the fabrication of a transistor (e.g., PMOS), either around the time of threshold voltage adjust and well implants prior to gate formation, or as a through-gate implant around the time of source/drain extension implants. With its implant depth targeted about at or less than the peak of the concentration of the dopant used for well and channel stop implants (e.g., phosphorus) and away from the substrate surface, the migration control implant suppresses the diffusion of the well and channel stop dopant to the surface region, a more retrograde concentration profile is achieved, and inter-transistor threshold voltage mismatch is improved without other side effects. A compensating through-gate threshold voltage adjust implant (e.g., of arsenic) or a threshold voltage adjust implant of increased dose can increase the magnitude of the threshold voltage to a desired level.

A method of making a semiconductor device includes defining a first fin structure over a major surface of a substrate, wherein the first fin includes a first material. The method includes defining a second fin structure over the major surface of the substrate. Defining the second fin structure includes forming a lower portion of the second fin structure, closest to the substrate, having the first material, and forming an upper portion of the second fin structure, farthest from the substrate, having a second material different from the first material. The method includes forming a dielectric material over the substrate and between the first and second fin structures. The method includes removing the upper portion of the second fin structure, wherein removing the upper portion of the second fin structure includes reducing a height of the second fin structure to be less than a height of the first fin structure.

Variations of characteristics of a semiconductor device provided with a power MOSFET having a super junction structure are suppressed, and reliability of the semiconductor device is improved. A trench embedding an insulating film, which constitutes an insulator column therein, is formed in a first main surface of a semiconductor substrate whose crystal plane is a (110) plane. A crystal plane of a side surface of the trench in a short-side direction is a (111) plane, and a p-type diffusion layer constituting a p-column is formed in the above-mentioned side surface.

The present disclosure describes a system and a method for an ion implantation (IMP) process. The system includes an ion implanter configured to scan an ion beam over a target for a range of angles, a tilting mechanism configured to support and tilt the target, an ion-collecting device configured to collect a distribution and a number of ejected ions from the ion beam scan over the target, and a control unit configured to adjust a tilt angle based on a correction angle determined based on the distribution and number of ejected ions.

The present disclosure provides a method for forming a semiconductor device containing MOS transistors both with and without source/drain extension regions in a semiconductor substrate having a semiconductor material on either side of a gate structure including a gate electrode on a gate dielectric formed in a semiconductor material. In devices with source/drain extensions, a diffusion suppression species of one or more of indium, carbon and a halogen are used. The diffusion suppression implant can be selectively provided only to the semiconductor devices with drain extensions while devices without drain extensions remain diffusion suppression implant free.

An integrated circuit including a substrate with a fin extending from a surface of the substrate. The fin includes a source region, a drain region, and a body region. The source region includes an outer region having a first conductivity type complementary to a second conductivity type of an outer region of the body and an interior-positioned conductive region having the second conductivity type.