A silicon carbide semiconductor device has a silicon carbide substrate and an insulating film. The silicon carbide substrate includes a termination region having a peripheral edge, and an element region surrounded by the termination region. The insulating film is provided on the termination region. The termination region includes a first impurity region having a first conductivity type, and a field stop region having the first conductivity type, being in contact with the first impurity region and having a higher impurity concentration than the first impurity region. The field stop region is at least partially exposed at the peripheral edge.

The present disclosure relates to a novel neuron circuit using a p-n-p-n diode to realize small size and low power consumption. The neuron circuit according to one embodiment of the present disclosure may generate potential by charging current input from synapses through a capacitor. In this case, when the generated potential exceeds a critical value, the neuron circuit may generate and output a spike voltage corresponding to the generated potential using a p-n-p-n diode connected to the capacitor.

The present disclosure relates to a novel neuron circuit using a p-n-p-n diode to realize small size and low power consumption. The neuron circuit according to one embodiment of the present disclosure may generate potential by charging current input from synapses through a capacitor. In this case, when the generated potential exceeds a critical value, the neuron circuit may generate and output a spike voltage corresponding to the generated potential using a p-n-p-n diode connected to the capacitor.

This application provides a cell structure and its related semiconductor device. Said cell structure includes a semiconductor substrate. In said semiconductor substrate, there are a plurality of first and second trench units. A carrier barrier region and an electric field shielding region corresponding to the first and second trench units are provided at a bottom of each trench. Conductive materials are provided in the trenches to correspondingly form two gate regions. A source-body region is provided between adjacent first trench units and in contact with a first metal layer on a top portion of the semiconductor substrate. A floating region is provided between the first and second trench units and is isolated from a second metal layer by an insulating dielectric. More than one source region is provided in the surface of the source-body region close to a side edge of at least one of the first trench units and the second trench units. A first semiconductor region and the second metal layer in contact with the first semiconductor region are provided at a bottom portion of the semiconductor substrate. This application improves the offset tolerance of the trench etching window through the design of the floating region, to stabilize the gate control performance after the device is fabricated.

This application provides a cell structure and its related semiconductor device. Said cell structure includes a semiconductor substrate. In said semiconductor substrate, there are a plurality of first and second trench units. A carrier barrier region and an electric field shielding region corresponding to the first and second trench units are provided at a bottom of each trench. Conductive materials are provided in the trenches to correspondingly form two gate regions. A source-body region is provided between adjacent first trench units and in contact with a first metal layer on a top portion of the semiconductor substrate. A floating region is provided between the first and second trench units and is isolated from a second metal layer by an insulating dielectric. More than one source region is provided in the surface of the source-body region close to a side edge of at least one of the first trench units and the second trench units. A first semiconductor region and the second metal layer in contact with the first semiconductor region are provided at a bottom portion of the semiconductor substrate. This application improves the offset tolerance of the trench etching window through the design of the floating region, to stabilize the gate control performance after the device is fabricated.

A MOS controlled thyristor device according to the concept of the present invention includes a substrate comprising a first surface and a second surface, which face each other, gate patterns disposed on the first surface, a cathode electrode configured to cover the gate patterns, and an anode electrode disposed on the second surface, The substrate includes a lower emitter layer having a first conductive type, a lower base layer having a second conductive type on the lower emitter layer, an upper base region provided in an upper portion of the lower emitter layer and having a first conductive type, wherein the upper base region is configured to expose a portion of a top surface of the lower base layer, an upper emitter region having a second conductive type and provided in an upper portion of the upper base region, a first doped region having a first conductive type and a second doped region surrounded by the first doped region and having a second conductive type, wherein the first and second doped regions are provided in an upper portion of the upper emitter region, and a first doping pattern having a first conductive type, which is provided on one surface of the upper portion of the upper emitter region. The first doping pattern is interposed between the upper base region and the first doped region along a first direction parallel to the top surface of the substrate. The first doping pattern is configured to expose a top surface of the upper emitter region on the other surface of the upper portion of the upper emitter region. Each of the gate patterns is configured to cover portions of an exposed top surface of the lower base layer, an exposed top surface of the upper base layer, an exposed top surface of the upper emitter region, a top surface of the first doping pattern, and a top surface of the first doped region. The cathode electrode is configured to cover portions of top and side surfaces of the gate pattern, a top surface of the second doped region, and a top surface of the first doped region. The first conductive type and the second conductive type are different from each other.

The present invention forms an off-FET channel having a uniform and short length by using a self-align process of a method of forming and recessing a spacer, thereby enhancing the current driving capability of an off-FET and the uniformity of a device operation.

The present invention forms an off-FET channel having a uniform and short length by using a self-align process of a method of forming and recessing a spacer, thereby enhancing the current driving capability of an off-FET and the uniformity of a device operation.

A short-circuit semiconductor component comprises a semiconductor body, in which a rear-side base region of a first conduction type, an inner region of a second complementary conduction type, and a front-side base region of the first conduction type are disposed. The rear-side base region is electrically connected to a rear-side electrode, and the front-side base region is electrically connected to a front-side electrode. A turn-on structure, which is an emitter structure of the second conduction type, is embedded into the front-side base region and/or rear-side base region and is covered by the respective electrode and is electrically contacted with the electrode placed on the base region respectively embedding it. It can be turned on by a trigger structure which can be activated by an electrical turn-on signal. In the activated state, the trigger structure injects an electrical current surge into the semiconductor body, which irreversibly destroys a semiconductor junction.

A short-circuit semiconductor component comprises a semiconductor body, in which a rear-side base region of a first conduction type, an inner region of a second complementary conduction type, and a front-side base region of the first conduction type are disposed. The rear-side base region is electrically connected to a rear-side electrode, and the front-side base region is electrically connected to a front-side electrode. A turn-on structure, which is an emitter structure of the second conduction type, is embedded into the front-side base region and/or rear-side base region and is covered by the respective electrode and is electrically contacted with the electrode placed on the base region respectively embedding it. It can be turned on by a trigger structure which can be activated by an electrical turn-on signal. In the activated state, the trigger structure injects an electrical current surge into the semiconductor body, which irreversibly destroys a semiconductor junction.