A semiconductor device includes a first silicon carbide semiconductor layer, a source including a source pad and a source wiring, a gate including a gate pad and a gate wiring, first unit cells disposed in a first element region, and second unit cells disposed in a second element region. In a plan view, the first and second element regions are adjacent to each other with the gate wiring between the first and second element regions. A first electrode including the gate electrode of each first unit cell is disposed in the first element region and electrically connected to the gate. A second electrode including the gate electrode of each second unit cell is disposed in the second element region and not electrically connected to the gate. The first and second electrodes are separated below the gate wiring.

A photo relay includes an illuminating unit, a photoelectric conversion IC, a first MOS IC and a second MOS IC. The illuminating unit receives an input signal to generate an illuminating signal. The photoelectric conversion IC receives the illuminating signal to generate a voltage control signal accordingly. The second MOS IC is reversely stacked on the first MOS IC, such that the source electrodes of the two MOS ICs are electrically connected, and the gate electrodes of the two MOS ICs are electrically connected through a gate connection structure for receiving the voltage control signal, and the drain electrodes of the two MOS ICs generate an output signal according to the received voltage control signal.

Aspects of the present disclosure describe MOSFET devices that have snubber circuits. The snubber circuits comprise one or more resistors with a dynamically controllable resistance that is controlled by changes to a gate and/or drain potentials of the one or more MOSFET structures during switching events.

This invention discloses a semiconductor device disposed in a semiconductor substrate. The semiconductor device includes a first semiconductor layer of a first conductivity type on a first major surface. The semiconductor device further includes a second semiconductor layer of a second conductivity type on a second major surface opposite the first major surface. The semiconductor device further includes an injection efficiency controlling buffer layer of a first conductivity type disposed immediately below the second semiconductor layer to control the injection efficiency of the second semiconductor layer.

A semiconductor device includes a plurality of drift regions of a plurality of field effect transistor structures arranged in a semiconductor substrate. The plurality of drift regions has a first conductivity type. The semiconductor device further includes a plurality of compensation regions arranged in the semiconductor substrate. The plurality of compensation regions has a second conductivity type. Each drift region of the plurality of drift regions is arranged adjacent to at least one compensation region of the plurality of compensation regions. The semiconductor device further includes a Schottky diode structure or metal-insulation-semiconductor gated diode structure arranged at the semiconductor substrate.

A semiconductor device includes a first load terminal, a second load terminal and a semiconductor body coupled to the first load terminal and the second load terminal. The semiconductor body is configured to conduct a load current along a load current path between the first load terminal and the second load terminal. The semiconductor device further includes a control electrode electrically insulated from the semiconductor body and configured to control a part of the load current path, and an electrically floating sensor electrode arranged adjacent to the control electrode. The sensor electrode is electrically insulated from each of the semiconductor body, and the control electrode and is capacitively coupled to the load current path.

A semiconductor device includes a semiconductor substrate having an outer rim, a plurality of switchable cells defining an active area, and an edge termination region arranged between the switchable cells and the outer rim. Each of the switchable cells includes a gate electrode structure. The semiconductor device further includes a gate metallization in contact with the gate electrode structure. The active area includes at least a first switchable region having a first specific transconductance and at least a second switchable region having a second specific transconductance which is different from the first specific transconductance. The second switchable region is arranged between the gate metallization and the first switchable region. A ratio of the area of the second switchable region to the total area of the switchable regions is in a range from 5% to 50%.

An apparatus includes a drain and a source on opposing sides of an epitaxial layer, a plurality of gates formed in the epitaxial layer, a source contact connected to the source, a gate contact connected to the plurality of gates, a drain contact on opposing sides of the epitaxial layer of the source contact, a gate-source electrostatic discharge (ESD) diode connected between the gate contact and the source contact, and a breakdown voltage enhancement and leakage prevention structure formed underneath the gate-source ESD diode structure, wherein the breakdown voltage enhancement and leakage prevention structure comprises a body ring structure.

A technique relates to semiconductors. A bottom terminal of a transistor and bottom plate of a capacitor are positioned on the substrate. A spacer is arranged on the bottom terminal of the transistor. A transistor channel region extends vertically from the bottom terminal through the spacer to contact a top terminal of the transistor. A capacitor channel region extends vertically from the bottom plate to contact a top plate of the capacitor. A first gate stack is arranged along sidewalls of the transistor channel region and is in contact with the spacer. A second gate stack is arranged along sidewalls of the capacitor channel region and is disposed on the bottom plate. A distance from a bottom of the first gate stack to a top of the bottom terminal is greater than a distance from a bottom of the second gate stack to a top of the bottom plate.

A semiconductor device includes MOSFET cells having a drift region of a first conductivity type. A first and second active area trench are in the drift region. A split gate uses the active trenches as field plates or includes planar gates between the active trenches including a MOS gate electrode (MOS gate) and a diode gate electrode (diode gate). A body region of the second conductivity type in the drift region abutts the active trenches. A source of the first conductivity type in the body region includes a first source portion proximate to the MOS gate and a second source portion proximate to the diode gate. A vertical drift region uses the drift region below the body region to provide a drain. A connector shorts the diode gate to the second source portion to provide an integrated channel diode. The MOS gate is electrically isolated from the first source portion.