In an aspect, an electronic device can include a substrate, a semiconductor layer overlying the substrate and including a mesa adjacent to a trench, and a doped region within the semiconductor layer. The doped region extends across an entire width of the mesa and contacts the lowermost point of the trench. A charge pocket can be located between an elevation of the peak concentration of the doped region and an elevation of the upper surface of the substrate. In another aspect, a process includes patterning a semiconductor layer to define a trench, forming a sacrificial layer within the trench, removing the sacrificial layer from a bottom of the trench, doping a portion of the semiconductor layer that is along the bottom of the trench while a remaining portion of the sacrificial layer is along a sidewall of the trench.

A high-speed diode includes an n-type semiconductor layer and a p-type semiconductor layer which is laminated on the n-type semiconductor layer, where a pn junction is formed in a boundary portion between the n-type semiconductor layer and the p-type semiconductor layer, and crystal defects are formed such that the frequency of appearance is gradually decreased from the upper surface of the p-type semiconductor layer toward the bottom surface of the n-type semiconductor layer.

A method of determining whether a silicon-carbide semiconductor device, which has a metal oxide semiconductor (MOS) gate structure and a built-in diode, is a conforming product. The method includes measuring an ON voltage of the silicon carbide semiconductor device, passing a forward current through the built-in diode of the silicon carbide semiconductor device, measuring another ON voltage of the silicon carbide semiconductor device, which is the ON voltage of the silicon carbide semiconductor device after passing the forward current, calculating a rate of change between the ON voltage and the another ON voltage, and determining that the silicon carbide semiconductor device is a conforming product unless the calculated rate of change is less than 3%.

Provided is a vertical MOSFET in which a conduction deterioration phenomenon is prevented during a current return operation and an on-voltage is low during the current return operation. A semiconductor device includes a hole barrier region that is provided between a second-conductivity-type body region and a first-conductivity-type epitaxial layer below a second-conductivity-type body contact region and functions as a potential barrier to a hole which flows from a source electrode to the first-conductivity-type epitaxial layer through the second-conductivity-type body contact region and the second-conductivity-type body region.

A semiconductor device includes a source metallization, a source region of a first conductivity type in contact with the source metallization, a body region of a second conductivity type which is adjacent to the source region. The semiconductor device further includes a first field-effect structure including a first insulated gate electrode and a second field-effect structure including a second insulated gate electrode which is electrically connected to the source metallization. The capacitance per unit area between the second insulated gate electrode and the body region is larger than the capacitance per unit area between the first insulated gate electrode and the body region.

There are provided a transistor including a first semiconductor layer of a first conductivity type, a second semiconductor layer thereabove, a first impurity region of a second conductivity type provided in an upper layer part of the second semiconductor layer, a second impurity region of a first conductivity type provided in an upper layer part of the first impurity region, a gate electrode facing the first impurity region and the second semiconductor layer with a gate insulating film interposed in between, and first and second main electrodes; a parasitic transistor with the second impurity region as a collector, the first and the second semiconductor layers as an emitter, and the first impurity region as a base; a parasitic diode with the first impurity region as an anode, and the first and the second semiconductor layers as a cathode; and a pn junction diode with the first impurity region as an anode, and the second impurity region as a cathode.

A gate drive circuit has a capacitor and a gate drive voltage source connected in series with a gate terminal of a voltage-driven switching device. The gate drive source voltage feeds, as a gate drive voltage, a voltage higher than the sum of the voltage applied to a gate-source parasitic capacitance of the switching device when the switching device is in a steady ON state and the voltage applied to, of any circuit component interposed between the gate drive voltage source and the gate terminal of the switching device, a circuit component other than the capacitor (such as an upper transistor forming the output stage of the driver). No other circuit component (such as a resistor connected in parallel with the capacitor) is essential but the capacitor as the sole circuit component to be directly connected to the gate terminal of the switching device.

A semiconductor power device having shielded gate structure in an active area and having ESD clamp diode with two poly-silicon layer process is disclosed, wherein: the shielded gate structure comprises a first poly-silicon layer to serve as a shielded electrode and a second poly-silicon layer to serve as a gate electrode, and the ESD clamp diode formed between two protruding electrodes is also formed by the first poly-silicon layer. A mask specially used to define the ESD clamp diode portion is saved.

According to various embodiments, a transistor model for a computer based simulation of a field effect transistor may include: a first electrical network coupled between a drain node, a source node and a gate node, wherein the first electrical network is configured to represent an electrical characteristic of the field effect transistor in a forward operation; a second electrical network coupled parallel to the first electrical network and between the source node and the drain node, wherein the second electrical network is configured to represent an electrical characteristic of the field effect transistor in at least one of a commutation operation and a reverse operation; wherein the second electrical network includes: a controlled first source representing a parasitic junction of the field effect transistor; at least one controlled second source representing a charge injection dependent parasitic impedance of the field effect transistor; wherein the controlled first source and the at least one controlled second source are coupled in parallel; and wherein the controlled first source and the at least one controlled second source are coupled via at least one parameter such that a charge injection from the parasitic junction into the parasitic impedance is considered.

A semiconductor device having a semiconductor substrate that includes a first-conductivity-type substrate and a first-conductivity-type epitaxial layer, and a plurality of trenches reaching a predetermined depth from a main surface of the semiconductor substrate to terminate in the first-conductivity-type epitaxial layer. The semiconductor substrate includes a hydrogen-donor introduced part, of which a concentration of a hydrogen donor is greatest at a depth position that is separate from bottoms of the trenches by a distance at least two times of the depth of the trenches. The impurity concentration of an impurity dopant of the first-conductivity-type substrate being lower than that of the first-conductivity-type epitaxial layer. A difference between a first resistivity, corresponding to a total impurity concentration of the impurity dopant and the hydrogen donor of the first-conductivity-type substrate, and a second resistivity, corresponding to the impurity concentration of the impurity dopant of the first-conductivity-type epitaxial layer, is at most 20%.