A semiconductor device includes a chip having a main surface, a trench resistance structure formed in the main surface, a gate pad that has a resistance value lower than that of the trench resistance structure and that is arranged on the trench resistance structure so as to be electrically connected to the trench resistance structure, and a gate wiring line that has a resistance value lower than that of the trench resistance structure and that is arranged on the trench resistance structure so as to be electrically connected to the gate pad via the trench resistance structure.

A method of manufacturing a vertical silicon carbide semiconductor device having an electrode on each of two main surfaces of a semiconductor chip in which an n-type low concentration buffer layer and an epitaxial layer are grown by epitaxy on a silicon carbide substrate. Defects extending from the silicon carbide substrate to the epitaxial layer and defects generated in the epitaxial layer during epitaxial growth are detected by a PL image of the n-type low concentration buffer layer; the defects generated in the epitaxial layer during the epitaxy are detected by a PL image of the epitaxial layer; the defects extending from the silicon carbide substrate to the epitaxial layer are detected by the difference between detection results; and semiconductor chips free of the defects extending from the silicon carbide substrate to the epitaxial layer are identified.

An SiC semiconductor device includes a chip that includes an SiC monocrystal and has a main surface, a trench structure that has a side wall and a bottom wall and is formed in the main surface, and a contact region of a first conductivity type that includes a first region formed in a region along the side wall in a surface layer portion of the main surface and a second region formed in a region along the bottom wall inside the chip and having an impurity concentration lower than an impurity concentration of the first region.

An SiC semiconductor device comprises: a chip that includes an SiC monocrystal and has a main surface; a trench structure that has a first side wall extending in an a-axis direction of the SiC monocrystal and a second side wall extending in an m-axis direction of the SiC monocrystal and is formed in the main surface; and a contact region of a first conductivity type that is formed in a region inside the chip along the trench structure at an interval in the m-axis direction from the first side wall.

A semiconductor device (1A) includes a chip (2) that includes an SiC monocrystal and has a main surface (3), a trench structure (20) that has a first side wall (22A) extending in an a-axis direction of the SiC monocrystal and a second side wall (22B) extending in an m-axis direction of the SiC monocrystal and is formed in the main surface, and a contact region (50) of a first conductivity type that is formed in a region inside the chip along the trench structure at an interval in the a-axis direction from the second side wall.

An electronic circuit is disclosed. The electronic circuit includes: a half-bridge with a first transistor device (1) and a second transistor device (1a); a first biasing circuit (3) connected in parallel with a load path of the first transistor device (1) and comprising a first electronic switch (31); a second biasing circuit (3a) connected in parallel with a load path of the second transistor device (1a) and comprising a second electronic switch (31a); and a drive circuit arrangement (DRVC). The drive circuit arrangement (DRVC) is configured to receive a first half-bridge input signal (Sin) and a second half-bridge input signal (Sina), drive the first transistor device (1) and the second electronic switch (31a) based on the first half-bridge input signal (Sin), and drive the second transistor device (1a) and the first electronic switch (31) based on the second half-bridge input signal (Sina).

A SiC epitaxial wafer of the present invention includes a SiC single crystal substrate, and a high concentration layer that is provided on the SiC single crystal substrate and has an average value of an n-type doping concentration of 110.sup.18/cm.sup.3 or more and 110.sup.19/cm.sup.3 or less, and in-plane uniformity of the doping concentration of 30% or less.

A silicon carbide semiconductor device being capable of operating at least 100 degree C., includes a semiconductor substrate having an active region, the semiconductor substrate having first and second surfaces opposite to each other, a first semiconductor region of an n type, provided in the semiconductor substrate, a second semiconductor region of a p type, provided in the active region, between the first surface of the semiconductor substrate and the first semiconductor region, and a device element structure including a pn junction between the second and first semiconductor regions that forms a body diode through which a current flows when the semiconductor device is turned on. A stacking fault area that is a sum of areas that contain stacking faults within an entire active region of the first surface of the semiconductor substrate in the first surface is set to be greater, the higher a breakdown voltage is set.

A silicon carbide semiconductor power transistor and a method of manufacturing the same. The silicon carbide semiconductor power transistor of the disclosure includes a substrate made of silicon carbide (SiC), a drift layer disposed on the substrate, a gate layer formed on the drift layer, a plurality of first and second well pick-up regions disposed in the drift layer, a plurality of source electrodes, and a plurality of contacts. A plurality of V-grooves is formed in the drift layer. A first opening is formed in the gate layer at a bottom of each of the V-grooves, and a second opening is formed in the gate layer at a top of the drift layer between the V-grooves. The plurality of contacts is disposed inside the second opening to be in direct contact with the second well pick-up regions.

An object of the present invention is to provide a novel technique for uniformizing a carrier concentration of an epitaxial layer.

The present invention is a method for uniformizing the carrier concentration of an epitaxial layer, the method including a growth step S10 of growing the epitaxial layer 20 under an equilibrium vapor pressure environment on the bulk layer 10. As described above, including the growth step S10 of growing the epitaxial layer 20 under an equilibrium vapor pressure environment can suppress the variation in the carrier concentration in the epitaxial layer 20.