The present disclosure provides a semiconductor structure and a manufacturing method therefor. In the semiconductor structure, a semiconductor substrate, a heterojunction and an in-situ insulation layer are disposed from bottom to top, a trench is provided in the in-situ insulation layer, and a transition layer is located on at least an in-situ insulation layer, the p-type semiconductor layer is located in the trench and on the gate region of the transition layer, and the heavily doped n-type layer is located on at least one of the p-type semiconductor layer in the gate region, the source region of the heterojunction, or the drain region of the heterojunction.

A multi-trench super junction IGBT device includes a metallization collector, a P-type substrate, a first N-type epitaxial layer located above the P-type substrate and a second N-type epitaxial layer located above the first N-type epitaxial layer. The second N-type epitaxial layer includes at least a first dummy MOS cell unit and a MOS cell unit, wherein the first dummy MOS cell unit includes a trench formed by reactive ion etching, a thermally grown gate oxide layer provided inside the trench and deposited heavily doped polysilicon located in the gate oxide layer.

A trench-gate MOSFET with electric field shielding region, has a substrate; a source electrode; a drain electrode; a semiconductor region with a first doping type formed on the substrate; a trench-gate, a plurality of electric field shielding regions with a second doping type formed under a surface of the semiconductor region, wherein the electric field shielding region intersects the trench-gate at an angle; a source electrode region formed on both sides of the trench-gate is divided into a plurality of source electrode sub-regions by the plurality of electric field shielding regions.

An n.sup.+ layer 3a connected to a source line SL at both ends, an n.sup.+ layer 3b connected to a bit line BL, a first gate insulating layer 4a formed on a semiconductor substrate 1 existing on an insulating film 2, a gate conductor layer 16a connected to a plate line PL, a gate insulating layer 4b formed on the semiconductor substrate, and a second gate conductor layer 5b connected to a word line WL and having a work function different from a work function of the gate conductor layer 16a are disposed on the semiconductor substrate, and data hold operation of holding, near a gate insulating film, holes generated by an impact ionization phenomenon or gate-induced drain leakage current inside a channel region 12 of the semiconductor substrate 1 and data erase operation of removing the holes from inside the substrate 1 and the channel region 12 are performed by controlling voltage applied to the source line SL, the plate line PL, the word line WL, and the bit line BL.

A preparation method for a flat cell ROM device, comprising the steps of: providing a substrate, and forming a P well on the substrate; forming a photomask layer on the P well and performing photoetching to form an injection window; injecting P-type ions in the formed injection window to form a P-type region; injecting N-type ions in the injection window so as to form an N-type region on the P-type region; and forming a gate oxide layer and a poly-silicon gate so as to complete the preparation of a device.

A power semiconductor device is disclosed. In one example, the device includes a semiconductor body coupled to a first load terminal structure and a second load terminal structure. An active cell field is implemented in the semiconductor body. The active cell field is surrounded by an edge termination zone. A plurality of first cells and a plurality of second cells are provided in the active cell field. Each first cell includes a first mesa, the first mesa including: a first port region and a first channel region. Each second cell includes a second mesa, the second mesa including a second port region. The active cell field is surrounded by a drainage region that is arranged between the active cell field and the edge termination zone.

The present disclosure provides semiconductor structures and fabrication methods thereof. An exemplary fabrication method includes providing a plurality of fins on a semiconductor substrate; forming an anti-diffusion layer, containing anti-diffusion ions, in the fins; forming an anti-punch through layer, containing anti-punch through ions, in the fins, a top surface of the anti-punch through layer being below a top surface of the anti-diffusion layer, and the anti-diffusion layer preventing the anti-punch through ions from diffusing toward tops of the fins; and performing a thermal annealing process.

A semiconductor device includes a JFET and a MOSFET cascode-connected to each other such that a source electrode of the JFET is connected to a drain electrode of the MOSFET. The JFET is configured such that a breakdown voltage between a gate layer and a body layer is set lower than a breakdown voltage of the MOSFET.

In a general aspect, a semiconductor device can include a semiconductor region, an active region disposed in the semiconductor region, and a termination region disposed on the semiconductor region and adjacent to the active region. The termination region can include a trench having a conductive material disposed therein. The termination region can further include a first cavity separating the trench from the semiconductor region. A portion of the first cavity can be disposed between a bottom of the trench and the semiconductor region. The termination region can also include a second cavity separating the trench from the semiconductor region.

According to one embodiment, a semiconductor device includes first, second, third nitride members, first, second, third electrodes, and a first insulating member. The first nitride member includes a first face along a first plane, a second face along the first plane, and a third face. The third face is connected with the first and second faces between the first and second faces. The third face crosses the first plane. The first face overlaps a part of the first nitride member. The second nitride member includes a first nitride region provided at the first face. The third nitride member includes a first nitride portion provided at the second face. The first electrode includes a first connecting portion. The second electrode includes a second connecting portion. The third electrode includes a first electrode portion. The first insulating member includes a first insulating region.