In an insulated trench gate device, polysilicon in the trench is etched below the top surface of the trench, leaving a thin gate oxide layer exposed near the top of the trench. An angled implant is conducted that implants dopants through the exposed gate oxide and into the side of the trench. If the implanted dopants are n-type, this technique may be used to extend an n+ source region to be below the top of the polysilicon in the trench. If the implanted dopants are p-type, the dopants may be used to form a p-MOS device that turns on when the polysilicon is biased with a negative voltage. P-MOS and n-MOS devices can be formed in a single cell using this technique, where turning on the n-MOS device turns on a vertical power switch, and turning on the p-MOS device turns off the power switch.

A silicon carbide semiconductor device includes first semiconductor areas and second semiconductor areas. The first semiconductor areas have a first semiconductor layer of a second conductivity type, a second semiconductor layer of a first conductivity type, first semiconductor regions of the second conductivity type, second semiconductor regions of the first conductivity type, gate electrodes, and first electrodes. The second semiconductor areas have the first semiconductor layer, the second semiconductor layer, third semiconductor regions of the second conductivity type, the gate electrodes, and the first electrodes. The first semiconductor regions include low- impurity-concentration regions and high-impurity-concentration regions. The third semiconductor regions have a potential equal to that of the first electrodes. The first semiconductor regions are connected to the third semiconductor regions by MOS structures. In the first semiconductor regions, the high-impurity-concentration regions are provided at positions different from positions facing the first electrodes.

An embedded NMOS triggered silicon controlled rectification device includes a P-type substrate, at least one rectifying zone, and at least one trigger. The rectifying zone includes a first N-type heavily doped area, an N-type well, and a first P-type heavily doped area. Alternatively, the device includes an N-type substrate, a first P-type well, at least one rectifying zone, and at least one trigger. The rectifying zone includes a second P-type well, a first N-type heavily doped area, and a first P-type heavily doped area. The trigger cooperates with the P-type substrate or the first P-type well to form at least one NMOSFET. The trigger is independent to the rectifying zone. The first P-type heavily doped area is arranged between the trigger and the first N-type heavily doped area.

An embedded NMOS triggered silicon controlled rectification device includes a P-type substrate, at least one rectifying zone, and at least one trigger. The rectifying zone includes a first N-type heavily doped area, an N-type well, and a first P-type heavily doped area. Alternatively, the device includes an N-type substrate, a first P-type well, at least one rectifying zone, and at least one trigger. The rectifying zone includes a second P-type well, a first N-type heavily doped area, and a first P-type heavily doped area. The trigger cooperates with the P-type substrate or the first P-type well to form at least one NMOSFET. The trigger is independent to the rectifying zone. The first P-type heavily doped area is arranged between the trigger and the first N-type heavily doped area.

An anti-static metal oxide semiconductor field effect transistor structure includes an anti-static body structure and a slave metal oxide semiconductor field effect transistor, the anti-static body structure includes: a main metal oxide semiconductor field effect transistor; a first silicon controlled rectifier, an anode thereof being connected to a drain of the main metal oxide semiconductor field effect transistor, a cathode and a control electrode thereof being connected to a source of the main metal oxide semiconductor field effect transistor; and a second silicon controlled rectifier, an anode thereof being connected to the drain of the main metal oxide semiconductor field effect transistor, a cathode thereof being connected to a gate of the main metal oxide semiconductor field effect transistor, a control electrode thereof being connected to the source or the gate of the main metal oxide semiconductor field effect transistor.

A power electronic arrangement includes a semiconductor switch structure configured to assume a forward conducting state. A steady-state current carrying capability of the semiconductor switch structure in the forward conducting state is characterized by a nominal current. The semiconductor switch structure is configured to conduct, in the forward conducting state, at least a part of a forward current in a forward current mode of the power electronic arrangement. A diode structure electrically connected in antiparallel to the semiconductor switch structure is configured to conduct at least a part of a reverse current in a reverse mode of the power electronic arrangement. A thyristor structure electrically connected in antiparallel to the semiconductor switch structure has a forward breakover voltage lower than a diode on-state voltage of the diode structure at a critical diode current value, the critical diode current value amounting to at most five times the nominal current.

A power transmission device includes a power transmission coil, a power-transmission resonance capacitor that forms, together with the power transmission coil, a power-transmission resonance mechanism, and a power transmission circuit electrically connected to the power-transmission resonance mechanism that intermittently applies a direct-current input voltage to the power-transmission resonance mechanism and causes the power transmission coil to generate an alternating-current voltage. The power transmission circuit includes a control circuit section including an oscillator, and a power circuit section formed of an integrated circuit sealed in a small-sized package with a plurality of terminals. The integrated circuit is electrically and directly connected to the power-transmission resonance mechanism. The control circuit section oscillates at a predetermined frequency and outputs a driving signal which is input to the power circuit section. The power circuit section intermittently applies a direct-current voltage to the power-transmission resonance mechanism using a transistor in the integrated circuit.

A method for depositing a metal chalcogenide on a substrate by cyclical deposition is disclosed. The method may include, contacting the substrate with at least one metal containing vapor phase reactant and contacting the substrate with at least one chalcogen containing vapor phase reactant. Semiconductor device structures including a metal chalcogenide deposited by the methods of the disclosure are also provided.

Electrical overstress protection via silicon controlled rectifier (SCR) trigger amplification control is provided. In certain configurations, an overstress protection circuit includes a control circuit for detecting presence of an overstress event between a first pad and a second pad of an interface, and a discharge circuit electrically connected between the first pad and the second pad and selectively activated by the control circuit. The interface corresponds to an electronic interface of an integrated circuit (IC), a System on a Chip (SoC), or System in-a-Package (SiP). The discharge circuit includes a first smaller SCR and a second larger SCR. In response to detecting an overstress event, the control circuit activates the smaller SCR, which in turn activates the larger SCR to provide clamping between the first pad and the second pad.

SCRs are a must for ESD protection in low voltagehigh speed I/O as well as ESD protection of RF pads due to least parasitic loading and smallest foot print offered by SCRs. However, conventionally designed SCRs in FinFET and Nanowire technology suffer from very high turn-on and holding voltage. This issue becomes more severe in sub-14 nm non-planar technologies and cannot be handled by conventional approaches like diode- or transient-turn-on techniques. Proposed invention discloses SCR concept for FinFET and Nanowire technology with diffused junction profiles with sub-3V trigger and holding voltage for efficient and robust ESD protection. Besides low trigger and holding voltage, the proposed device offers a 3 times better ESD robustness per unit area.