A method of manufacturing a semiconductor device includes preparing a light ion source, a first mask and a second mask. A side of a first region on a top surface of a semiconductor substrate is shielded by using the first mask. The top surface, with the side of the first region thereon being shielded with the first mask, is irradiated with light ions by operating the light ion source to introduce lattice defects at a specified depth on a side of a second region on the top surface. A side of the second region on a bottom surface of the semiconductor substrate is shielded by using the second mask. The bottom surface, with the side of the second region thereon being shielded with the second mask, is irradiated with light ions by operating the light ion source to introduce lattice defects at a specified depth on the side of the first region on the bottom surface.

A semiconductor device includes a first semiconductor region having first charge carriers of a first conductivity type and a second semiconductor region having second charge carriers. The first semiconductor region includes a transition region in contact with the second semiconductor region, the transition region having a first concentration of the first charge carriers, a contact region having a second concentration of the first charge carriers, wherein the second concentration is higher than the first concentration, and a damage region between the contact region and the transition region. The damage region is configured for reducing lifetime and/or mobility of the first charge carriers of the damage region as compared to the lifetime and/or the mobility of the first charge carriers of the contact region and the transition region.

This invention discloses a semiconductor device disposed in a semiconductor substrate. The semiconductor device includes a first semiconductor layer of a first conductivity type on a first major surface. The semiconductor device further includes a second semiconductor layer of a second conductivity type on a second major surface opposite the first major surface. The semiconductor device further includes an injection efficiency controlling buffer layer of a first conductivity type disposed immediately below the second semiconductor layer to control the injection efficiency of the second semiconductor layer.

A semiconductor device according to embodiments includes a p-type SiC layer having a first plane, a gate electrode, and a gate insulating layer provided between the first plane of the SiC layer and the gate electrode. The gate insulating layer includes a first layer, a second layer, and a first region. The second layer has a higher oxygen density than the first layer. The first region is provided between the first layer and the second layer and includes a first element, the first element being at least one element in the group of N (nitrogen), P (phosphorus), As (arsenic), Sb (antimony), and Bi (bismuth).

Methods for facilitating fabricating semiconductor structures are provided which include: providing a multilayer structure including a semiconductor layer, the semiconductor layer including a dopant and having an increased conductivity; selectively increasing, using electrochemical processing, porosity of the semiconductor layer, at least in part, the selectively increasing porosity utilizing the increased conductivity of the semiconductor layer; and removing, at least in part, the semiconductor layer with the selectively increased porosity from the multilayer structure. By way of example, the selectively increasing porosity may include selectively, anodically oxidizing, at least in part, the semiconductor layer of the multilayer structure.

A semiconductor device includes a plurality of drift regions of a plurality of field effect transistor structures arranged in a semiconductor substrate. The plurality of drift regions has a first conductivity type. The semiconductor device further includes a plurality of compensation regions arranged in the semiconductor substrate. The plurality of compensation regions has a second conductivity type. Each drift region of the plurality of drift regions is arranged adjacent to at least one compensation region of the plurality of compensation regions. The semiconductor device further includes a Schottky diode structure or metal-insulation-semiconductor gated diode structure arranged at the semiconductor substrate.

A semiconductor device includes a first load terminal, a second load terminal and a semiconductor body coupled to the first load terminal and the second load terminal. The semiconductor body is configured to conduct a load current along a load current path between the first load terminal and the second load terminal. The semiconductor device further includes a control electrode electrically insulated from the semiconductor body and configured to control a part of the load current path, and an electrically floating sensor electrode arranged adjacent to the control electrode. The sensor electrode is electrically insulated from each of the semiconductor body, and the control electrode and is capacitively coupled to the load current path.

To restrict the deterioration of properties in a semiconductor device due to hydrogen, provided is a semiconductor device including a semiconductor substrate; a hydrogen absorbing layer that is provided above a top surface of the semiconductor substrate and formed of a first metal having a hydrogen absorbing property; a nitride layer that is provided above the hydrogen absorbing layer and formed of a nitride of the first metal; an alloy layer that is provided above the nitride layer and formed of an alloy of aluminum and a second metal; and an electrode layer that is provided above the alloy layer and formed of aluminum. A pure metal layer of the second metal is not provided between the electrode layer and the nitride layer.

A semiconductor substrate having a first main surface and a transistor cell includes a drift region, a body region between the drift region and the first main surface, an active trench at the first main surface extending into the drift region, a gate insulating layer at sidewalls and a bottom side of the active trench, a gate conductive layer in the active trench, a source region in the body region, and adjacent to the active trench, a body trench at the first main surface extending into the drift region, the body trench being adjacent to the body region and to the drift region, an insulating layer at sidewalls and at a bottom side of the body trench, the insulating layer being asymmetric with respect to an axis extending perpendicular to the first main surface at a center of the body trench, and a conductive layer in the body trench.

A semiconductor device includes a semiconductor substrate having an outer rim, a plurality of switchable cells defining an active area, and an edge termination region arranged between the switchable cells and the outer rim. Each of the switchable cells includes a gate electrode structure. The semiconductor device further includes a gate metallization in contact with the gate electrode structure. The active area includes at least a first switchable region having a first specific transconductance and at least a second switchable region having a second specific transconductance which is different from the first specific transconductance. The second switchable region is arranged between the gate metallization and the first switchable region. A ratio of the area of the second switchable region to the total area of the switchable regions is in a range from 5% to 50%.