According to an aspect of the present disclosure, a semiconductor device includes a substrate including an IGBT region, and a diode region, a surface electrode provided on a top surface of the substrate and a back surface electrode provided on a back surface on an opposite side to the top surface of the substrate, wherein the diode region includes a first portion formed to be thinner than the IGBT region by the top surface of the substrate being recessed, and a second portion provided on one side of the first portion and thicker than the first portion.

A semiconductor device includes a backside contact and a substrate. An epitaxial field stop region may be formed on the substrate with a graded doping profile that decreases with distance away from the substrate, and an epitaxial drift region may be formed adjacent to the epitaxial field stop region. A frontside device may be formed on the epitaxial drift region.

The present technique relates to an electrostatic protective element that enables protective performance with respect to static electricity to be improved and to an electronic device. An electrostatic protective element includes: a first impurity region of a first conductivity type which is formed on the predetermined surface side of a semiconductor substrate; a second impurity region of a second conductivity type which is formed on the predetermined surface side of the semiconductor substrate so as to form a clearance in a horizontal direction with respect to the first impurity region; a collector contact which is formed on the predetermined surface side in the first impurity region, which has a higher concentration than the first impurity region, and which is an impurity region of the first conductivity type; a base contact which is formed on the predetermined surface side in the second impurity region, which has a higher concentration than the second impurity region, and which is an impurity region of the second conductivity type; and an emitter contact which is formed on the predetermined surface side in the second impurity region at a position that is closer to the collector contact than the base contact, which has a higher concentration than the second impurity region, and which is an impurity region of the first conductivity type. The present technique can be applied to, for example, an electronic device.

Various apparatuses, systems, methods, and media are disclosed to provide over-voltage protection to a data interface of a multi-protocol memory card that includes a first communication interface and a second communication interface that enable communication using different protocols. An interface voltage protection circuit includes a control circuit configured to receive a first supply voltage for operating the first communication interface. The interface voltage protection circuit further includes a pull-down circuit operatively connected with the control circuit, configured to pull down a voltage at a supply voltage rail of the second communication interface such that a voltage at a plurality of connector terminals of the second communication interface is lower than the first supply voltage.

Various apparatuses, systems, methods, and media are disclosed to provide over-voltage protection to a data interface of a multi-protocol memory card that includes a first communication interface and a second communication interface that enable communication using different protocols. An interface voltage protection circuit includes a control circuit configured to receive a first supply voltage for operating the first communication interface. The interface voltage protection circuit further includes a pull-down circuit operatively connected with the control circuit, configured to pull down a voltage at a supply voltage rail of the second communication interface such that a voltage at a plurality of connector terminals of the second communication interface is lower than the first supply voltage.

A diode is formed by a polycrystalline silicon bar which includes a first doped region with a first conductivity type, a second doped region with a second conductivity type and an intrinsic region between the first and second doped regions. A conductive layer extends parallel to the polycrystalline silicon bar and separated from the polycrystalline silicon bar by a dielectric layer. The conductive layer is configured to be biased by a bias voltage.

In a semiconductor device, a semiconductor substrate has an IGBT region and a FWD, and includes a first conductivity type drift layer, a second conductivity type base layer disposed on the drift layer, a second conductivity type collector layer disposed opposite to the base layer with respect to the drift layer in the IGBT region, and a first conductivity type cathode layer disposed opposite to the base layer with respect to the drift layer in the FWD region. The collector layer includes an extension portion that covers only a part of the cathode layer on a side adjacent to the drift layer. Alternatively, the collector layer includes an extension portion that entirely covers a region of the cathode layer adjacent to the drift layer, and has an area density of 3.5×10.sup.12 cm.sup.−2 or less.

Provided is a semiconductor device including: a buffer region having a doping concentration higher than a bulk donor concentration; a first low-concentration hydrogen peak in the buffer region; a second low-concentration hydrogen peak in the buffer region closer to a lower surface than the first low-concentration hydrogen peak; a high-concentration hydrogen peak in the buffer region closer to the lower surface than the second low-concentration hydrogen peak, the high-concentration hydrogen peak having a hydrogen chemical concentration higher than that of the second low-concentration hydrogen peak; and a flat region including a region between the two low-concentration hydrogen peaks and a region including the second low-concentration hydrogen peak, and having a doping concentration higher than a bulk donor concentration, an average value of the doping concentration being equal to or smaller than a local minimum value of a doping concentration between the second low-concentration hydrogen peak and the high-concentration hydrogen peak.

Provided is a semiconductor device including: a semiconductor substrate having a drift region of a first conductivity type; and a buffer region of the first conductivity type provided between the drift region and a lower surface of the semiconductor substrate and having a higher doping concentration than the drift region. The buffer region has two or more helium chemical concentration peaks arranged at different positions in a depth direction of the semiconductor substrate.

A semiconductor device includes a first semiconductor well. The semiconductor device includes a channel structure disposed above the first semiconductor well and extending along a first lateral direction. The semiconductor device includes a gate structure extending along a second lateral direction and straddling the channel structure. The semiconductor device includes a first epitaxial structure disposed on a first side of the channel structure. The semiconductor device includes a second epitaxial structure disposed on a second side of the channel structure, the first side and second side opposite to each other in the first lateral direction. The first epitaxial structure is electrically coupled to the first semiconductor well with a second semiconductor well in the first semiconductor well, and the second epitaxial structure is electrically isolated from the first semiconductor well with a dielectric layer.