An object of the present disclosure is to suppress decrease in withstand voltage and increase in ON voltage and to increase body diode current. An SiC-MOSFET includes: a source region formed on a surface layer of a base region; a gate electrode facing a channel region which is a region of the base region sandwiched between a drift layer and the source region via a gate insulating film; a source electrode having electrically contact with the source region; and a plurality of first embedded regions of a second conductivity type formed adjacent to a lower surface of the base region. The plurality of first embedded regions are formed immediately below at least both end portions of the base region, and three or more first embedded regions are formed to be separated from each other.

A method includes forming a layer stack with a plurality of first layers of a first doping type and a plurality of second layers of a second doping type complementary to the first doping type on top of a carrier. Forming the layer stack includes forming a plurality of epitaxial layers on the carrier. Forming each of the plurality of epitaxial layers includes depositing a layer of semiconductor material, forming at least two first implantation regions of one of a first type or a second type at different vertical positions of the respective layer of semiconductor material, and forming at least one second implantation region of a type that is complementary to the type of the first implantation regions, the first implantation regions and the second implantation regions being arranged alternatingly.

There is provided a semiconductor device including: a drift region of a first conductivity type disposed in a semiconductor substrate; a base region of a second conductivity type disposed above the drift region; an emitter region of the first conductivity type disposed above the base region; a plurality of trench portions arrayed in a predetermined array direction on a front surface side of the semiconductor substrate; a trench contact disposed on the front surface side of the semiconductor substrate between two adjacent trench portions; and a contact layer of the second conductivity type disposed under the trench contact and having a higher doping concentration than the base region, wherein a lower end of the trench contact is deeper than a lower end of the emitter region, and the emitter region and the contact layer are in contact with each other at a side wall of the trench contact.

An integrated circuit comprising an SGT MOSFET and a short channel SBR is disclosed. The SBR horizontally disposed in different areas to the SGT MOSFET on single chip creates a low potential barrier for majority carrier in MOS channel for switching loss reduction. Only one additional mask is required for integration of the short channel SBR having thinner gate oxide than the SGT MOSFET. Moreover, in some preferred embodiment, an MSO structure is applied to the shielded gate structure to further reduce the on-resistance.

Back-surface roughness of a back surface of a silicon carbide semiconductor device having a MOS gate structure in a first region that is a region within 30 μm of a cross section (lateral surface) of the device is at most 4 μm while the back-surface roughness in a second region other than the first region is at most 2 μm, the back surface of the silicon carbide semiconductor device is the back surface of the second electrode. In a method of manufacture, the back-surface roughness of the device is specified to meet a predetermined condition. Then, ON voltages of the device before and after a forward current is passed through body diodes of the device are measured, and a rate of change of the ON voltage while the forward current is passed through body diodes is calculated, and then the device having a calculated rate of change less than 3% is identified.

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 device includes a silicon carbide semiconductor substrate of a first conductivity type, a first semiconductor layer of the first conductivity type, a second semiconductor layer of the first conductivity type, a third semiconductor layer of the first conductivity type, a fourth semiconductor layer of a second conductivity type, first semiconductor regions of the first conductivity type, gate insulating films, gate electrodes, a first electrode, and a second electrode. When a current flows from the first electrode to the second electrode, a peak light emission intensity at a wavelength close to 390 nm is lower than a peak light emission intensity at a wavelength close to 500 nm.

Diodes, transistors, and other devices having a class IV channel region and a class III-V drift region are described. The class IV channel region, such as a Si channel region, is able to provide all associated advantages, such as ease of manufacturing of many different types of devices, using cost-effective materials and techniques. Meanwhile, the III-V drift region provides substantially lower R.sub.on_sp than a conventional class IV drift region, and substantially enhances the operational behaviors of resulting devices, without sacrificing other parameters, such as size or breakdown voltage.

A wide gap semiconductor device has: a first MOSFET region (M0) having a first gate electrode 10 and a first source region 30 provided in a first well region 20 made of a second conductivity type; a second MOSFET region (M1) provided below a gate pad 100 and having a second gate electrode 110 and a second source region 130 provided in a second well region 120 made of the second conductivity type; and a built-in diode region electrically connected to the second gate electrode 110. The second source region 130 of the second MOSFET region (M1) is electrically connected to the gate pad 100.

In a Schottky barrier diode region, a Schottky barrier diode is formed between an n-type drift layer and a metal layer, and in a body diode region, a p-type semiconductor region, a p-type semiconductor region, and a p-type semiconductor region are formed in order from a main surface side in the drift layer, and a body diode is formed between the p-type semiconductor region and the drift layer. An impurity concentration of the p-type semiconductor region is decreased lower than the impurity concentration of the p-type semiconductor regions, thereby increasing the reflux current flowing through the Schottky barrier diode and preventing the reflux current from flowing through the body diode.