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 JFET 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.

Methods for fabricating SiC MOSFETs using channeled ion implants are disclosed. By aligning the workpiece such that the ions pass through channels in the SiC hexagonal crystalline structure, it is possible to achieve deeper implants than are otherwise possible. Further, it was found that these channeled implants can be tailored to achieve box-like dopant concentrations. This allows channeled ion implants to be used to create the current spreading layer of the MOSFET, which is conventional fabricated using epitaxial growth. Further, these channeled implants can also be used to create the shields between adjacent transistors. Additionally, the use of channeled implants allows a reduction in the number of epitaxially growth processes that are used to create super junction MOSFETs.

An insulated-gate semiconductor device, which has trenches arranged in a chip structure, the trenches defining both sidewalls in a first and second sidewall surface facing each other, includes: a first unit cell including a main-electrode region in contact with a first sidewall surface of a first trench, a base region in contact with a bottom surface of the main-electrode region and the first sidewall surface, a drift layer in contact with a bottom surface of the base region and the first sidewall surface, and a gate protection-region in contact with the second sidewall surface and a bottom surface of the first trench; and a second unit cell including an operation suppression region in contact with a first sidewall surface and a second sidewall surface of a second trench, wherein the second unit cell includes the second trench located at one end of an array of the trenches.

A method includes orienting a silicon carbide layer to a first crystal channel direction relative to a first ion beam and implanting phosphorous into the silicon carbide layer using the first ion beam to define a first doped region in the silicon carbide layer. A deviation angle between the first crystal channel direction and the first ion beam is less than ±1° and the first crystal channel direction comprises a <0001> direction or a <11-23> direction.

A drift layer is formed of silicon carbide and has a first conductivity type. A trench bottom protective layer is provided on a bottom portion of a gate trench and has a second conductivity type. A depletion suppressing layer is provided between a side surface of the gate trench and the drift layer, extends from a lower portion of a body region up to a position deeper than the bottom portion of the gate trench, has the first conductivity type, and has an impurity concentration of the first conductivity type higher than that of the drift layer. The impurity concentration of the first conductivity type of the depletion suppressing layer is reduced as the distance from the side surface of the gate trench becomes larger.

The present invention relates to the field of semiconductors, and discloses a manufacturing method of a super junction and a super-junction Schottky diode thereof. The manufacturing method of the super junction includes forming an epitaxial layer on the surface of a wide-bandgap semiconductor substrate by an epitaxial growth process; implanting first doping ions into at least part of a region of the epitaxial layer along a preset crystal orientation of the wide-bandgap semiconductor to form a first conductive type region; and implanting second doping ions into at least part of the first conductive type region along the preset crystal orientation of the wide-bandgap semiconductor to form a second conductive type region, wherein the second doping ions and the first doping ions have different conductive types, and the preset crystal orientation is a crystal orientation which enables the doping ions to generate a channel effect when the doping ions are implanted along the preset crystal orientation.

A semiconductor device has a substrate. The substrate can be multiple layers. A first semiconductor layer made of a first semiconductor material is disposed over the substrate. The first semiconductor material can be substantially defect-free silicon carbide. A second semiconductor layer made of a second semiconductor material dissimilar from the first semiconductor material is disposed over the first semiconductor layer. The second semiconductor material is silicon. A third layer can be disposed between the first semiconductor layer and second semiconductor layer. A semiconductor device is formed in the second semiconductor layer. The semiconductor device can be a power MOSFET or diode. The second semiconductor layer with the electrical component provides a first portion of a breakdown voltage for the semiconductor device and the first semiconductor layer and substrate provide a second portion of the breakdown voltage for the semiconductor device.

A semiconductor device is provided. In an example, the semiconductor device includes a trench gate structure in a silicon carbide (SiC) semiconductor body. The semiconductor device includes a source region of a first conductivity type that adjoins the trench gate structure in a first segment. The semiconductor device includes a semiconductor region of a second conductivity type. The semiconductor region includes a first sub-region arranged below the source region in the first segment, and a second sub-region arranged in a second segment that adjoins the first segment. The semiconductor device includes a current spread region of the first conductivity type. The current spread region includes a first sub-region that adjoins the trench gate structure in the first segment at a vertical distance to a first surface of the SiC semiconductor body, and a second sub-region that is spaced from the trench gate structure in the second segment at the vertical distance to the first surface by a lateral distance.

The present disclosure relates a semiconductor device using a super junction structure, and includes: a semiconductor base body of a first conductivity type; a pillar part including a plurality of first pillars of a first conductivity type and a plurality of second pillars of a second conductivity type provided on the semiconductor base body to protrude in a thickness direction of the semiconductor base body; a pillar surrounding part of a first conductivity type or a second conductivity type provided around the pillar part; and a semiconductor element in which the pillar part is provided as an active region, wherein the plurality of first and second pillars have a striped shape in a plan view, and are alternately arranged in parallel to each other in a pillar width direction perpendicular to a longitudinal direction of each of the pillars.

A method of implanting an implant species into a substrate at different depths is described. The method includes forming an implant mask over the substrate. The implant mask includes a first implant zone designed as an opening and a second implant zone designed as a block array. The implant species is implanted through the implant mask under an implant angle tilted against a block plane, such that a first implant area is formed by the implant species at a first depth in the substrate beneath the first implant zone and a second implant area is formed by the implant species at a second depth in the substrate beneath the second implant zone. The first depth is greater than the second depth.