An object of the present disclosure is to achieve a stable current sensing operation and suppress decrease in main current at a low temperature of 0° C. or less in a silicon carbide semiconductor device. An SiC-MOSFET includes: a main cell outputting main current; and a sense cell outputting sense current proportional to the main current, wherein temperature dependent properties of the main current differ in accordance with threshold voltage of the main cell, temperature dependent properties of the sense current differ in accordance with threshold voltage of the sense cell, the threshold voltage of the main cell is smaller than the threshold voltage of the sense cell, and in a temperature of 0° C. or less, an inclination of the temperature dependent properties of the main current is smaller than an inclination of the temperature dependent properties of the sense current.

A semiconductor device includes a capacitance adjusting region. The capacitance adjusting region includes a first semiconductor layer of a first conductivity type, a second semiconductor layer of a second conductivity type, and a plurality of control trench gates. The first semiconductor layer is provided as a surface layer at an upper surface of the semiconductor substrate. The second semiconductor layer is selectively provided at an upper surface of the first semiconductor layer. The second semiconductor layer contacts a side surface of each of the control trench gates. The first semiconductor layer and the second semiconductor layer are electrically connected to an emitter electrode of a transistor. A control trench electrode of at least one control trench gate is electrically connected to a gate electrode of the transistor.

A first semiconductor region, a second semiconductor region, and a third semiconductor region are arranged in layers. Trenches penetrate through the second semiconductor region and reach the first semiconductor region. Each of the trenches may include a gate electrode, and an insulating film insulating the gate electrode from the first semiconductor region and the second semiconductor region. An upper electrode is electrically connected to the second semiconductor region and the third semiconductor region. A fourth semiconductor region of the second conductivity type is arranged on an outer side of the trench of which the gate electrode is an outermost gate electrode in a plan view. An edge trench is arranged on an outer side of the fourth semiconductor region. The fourth semiconductor region is electrically connected to the upper electrode and a bottom of the fourth semiconductor may be arranged deeper than a bottom of the second semiconductor region.

A semiconductor device includes: a chip having a main surface; a first conductive type first region formed on a surface layer portion of the main surface; a second conductive type second region formed on a surface layer portion of the first region; a drain region formed on a surface layer portion of the second region; a source region formed on the surface layer portion of the first region at a distance from the second region; and a second conductive type floating region formed in the first region at a thickness position between a bottom portion of the first region and a bottom portion of the second region and being spaced apart from the bottom portion of the second region, wherein the floating region faces the second region with a portion of the first region interposed between the floating region and the second region.

The present application relates to a semiconductor transistor device that includes a Schottky diode electrically connected in parallel to a body diode formed between a body region and a drift region. A diode junction of the Schottky diode is formed adjacent to the drift region and is arranged vertically above a lower end of the body region.

A trench metal-oxide-semiconductor field-effect transistor (MOSFET) device comprises an active cell area including a plurality of superjunction trench power MOSFETs, and a Schottky diode area including a plurality of Schottky diodes formed in the drift region having the superjunction structure. Each of the integrated Schottky diodes includes a Schottky contact between a lightly doped semiconductor layer and a metallic layer.

A shield trench power device such as a trench MOSFET or IGBT employs a gate structure with an underlying polysilicon shield region overlying a shield region in an epitaxial or crystalline layer of the device. The polysilicon region may be laterally confined by spacers in a gate trench and may contact or be isolated from the underlying shield region. Alternatively, the polysilicon region may be replaced with an insulating region.

In a RC-IGBT chip, an anode electrode film and an emitter electrode film are arranged with a distance therebetween. The anode electrode film and the emitter electrode film are electrically connected by a wiring conductor having an external impedance and an external impedance. The external impedance and the external impedance include the resistance of the wiring conductor and the inductance of the wiring conductor.

A power device includes: a diode section; a semiconductor body; a drift region extending into the diode section; trenches in the diode section and extending along a vertical direction into the semiconductor body, two adjacent trenches defining a respective mesa portion in the semiconductor body; a body region in the mesa portions; in the diode section, a barrier region between the body and drift regions and having a dopant concentration at least 100 times greater than an average dopant concentration of the drift region and a dopant dose greater than that of the body region. The barrier region has a lateral structure according to which at least 50% of the body region in the diode section is coupled to the drift region at least by the barrier region, and at least 5% of the body region in the diode section is coupled to the drift region without the barrier region.

Disclosed is a semiconductor device including a semiconductor layer having a main surface, a first conductivity type drift region formed at a surface layer part of the main surface, a super junction region having a first conductivity type first column region and a second conductivity type second column region, a second conductivity type low resistance region formed at the surface layer part of the drift region and having an impurity concentration in excess of that of the second column region, a region insulating layer formed on the main surface and covering the low resistance region such as to cause part of the low resistance region to be exposed, a first pad electrode formed on the region insulating layer such as to overlap with the low resistance region, and a second pad electrode formed on the main surface and electrically connected to the second column region and the low resistance region.