The present invention provides a FinFET device, including at least one fin structure, wherein the fin structure has a first-type well region, and a second-type well region adjacent to the first-type well region, a trench located in the fin structure and disposed between the first-type well region and the second-type well region, an insulating layer disposed in the trench, and a metal gate crossing over and disposed on the insulating layer.

A semiconductor apparatus has a silicon carbide substrate heavily doped with the first conductivity type and a lightly doped silicon carbide drift region of the first conductivity type over the silicon carbide substrate. A first body region in the drift region is doped with second conductivity type opposite the first. A first source region in the first body region is heavily doped with the first conductivity type. A gate trench is formed in the first source region and first body region. At least one sidewall of the gate trench is parallel to a crystal plane of the silicon carbide structure having greater carrier mobility than a C-face thereof. The gate trench extends a length of the first body region and the source region to a separation region laterally adjacent to the first region wherein the separation region is in the drift region.

A power metal-oxide-semiconductor field-effect transistor (MOSFET) includes a substrate, a drift layer over the substrate, and a spreading layer over the drift layer. The spreading layer includes a pair of junction implants separated by a junction gate field effect (JFET) region. A gate oxide layer is on top of the spreading layer. The gate contact is on top of the gate oxide layer. Each one of the source contacts are on a portion of the spreading layer separate from the gate oxide layer and the gate contact. The drain contact is on the surface of the substrate opposite the drift layer.

A semiconductor device in which current sensing accuracy is maintained while ruggedness of a current sensing region is improved. The semiconductor device includes a semiconductor substrate; a main element provided on the semiconductor substrate and having a first trench gate structure including a first trench disposed on a first main surface side of the semiconductor substrate; a gate insulating film disposed along an inner wall of the first trench; and a gate electrode disposed inside the first trench; and a current detecting element for detecting a current flowing into the semiconductor substrate when the main element is operating provided on the semiconductor substrate and having a second trench gate structure including a second trench disposed on the first main surface side of the semiconductor substrate; the gate insulating film disposed along an inner wall of the second trench; and the gate electrode disposed inside the second trench.

The present invention provides a vertical double-diffused metal-oxide semiconductor field-effect transistor and a manufacturing method. The manufacturing method comprises: providing a substrate of a first conductive type; growing a first epitaxial layer of the first conductive type above the substrate; forming column regions of the first conductive type and column regions of a second conductive type spaced in a staggered manner above the first epitaxial layer; forming a third epitaxial layer of the first conductive type above the column regions of the first conductive type, and forming a well region of the second conductive type above the column regions of the second conductive type; forming a gate region on a surface of the third epitaxial layer; forming a source region of the first conductive type in the well region of the second conductive type; and forming a gate metal layer, a source metal layer, and a drain metal layer.

A source region of a MOSFET includes a source contact region connected to a source electrode, a source extension region adjacent to a channel region of a well region, and a source resistance control region provided between the source extension region and the source contact region. The source resistance control region includes a low concentration source resistance control region which has an impurity concentration lower than that of the source contact region or the source extension region and a high concentration source resistance control region which is formed between the well region and the low concentration source resistance control region and has an impurity concentration higher than that of the low concentration source resistance control region.

A semiconductor device includes an N-type silicon carbide layer, a P-type region, an N-type source region, a P-type contact region, a gate insulating film, a gate electrode, and a source electrode on the front surface side of an N-type silicon carbide substrate. A drain electrode is located on the back surface of the N-type silicon carbide substrate. A life time killer introduction region is located along an entire interface of the N-type silicon carbide layer and the bottom face of the P-type region. The life time killer is introduced by implanting helium or protons from the back surface side of the N-type silicon carbide substrate after forming a surface structure of an element on the front surface side of the N-type silicon carbide substrate and before forming the drain electrode.

An electric circuit includes a semiconductor device. The semiconductor device includes a first transistor and a second transistor in a common semiconductor substrate. The first transistor is of the same conductivity type as the second transistor. A first source region of the first transistor is electrically connected to a first source terminal via a first main surface of the semiconductor substrate. A second drain region of the second transistor is electrically connected to a second drain terminal via a first main surface of the semiconductor substrate. A first drain region of the first transistor and a second source region of the second transistor are electrically connected to an output terminal via a second main surface of the semiconductor substrate. The electric circuit further includes a control circuit operable to control a first gate electrode of the first transistor and a second gate electrode of the second transistor.

A method for manufacturing a semiconductor device includes providing a semiconductor substrate having a first side. A trench having a bottom is formed. The trench separates a first mesa region from a second mesa region formed in the semiconductor substrate. The trench is filled with an insulating material, and the second mesa region is removed relative to the insulating material filled in the trench to form a recess in the semiconductor substrate. In a common process, a first silicide layer is formed on and in contact with a top region of the first mesa region at the first side of the semiconductor substrate and a second silicide layer is formed on and in contact with the bottom of the recess.

A semiconductor device includes a vertical gate electrode in a gate trench in a semiconductor substrate, and a lateral gate electrode over the semiconductor substrate and adjacent the gate trench, where the lateral gate electrode results in improved electrical performance of the semiconductor device. The improved electrical performance includes an improved avalanche current tolerance in the semiconductor device. The improved electrical performance includes a reduced impact ionization under the gate trench. The improved electrical performance includes a reduced electric field under the gate trench. The lateral gate electrode results in an improved thermal stability in the semiconductor device.