A semiconductor device includes an IGBT region in which an IGBT element is formed and an FWD region in which an FWD element is formed. The IGBT region includes a first region and a second region different from the first region. The FWD region and the first region of the IGBT region have a carrier extraction portion that facilitates extraction of carriers injected from a second electrode compared to the second region when a forward bias for causing the FWD element to operate as a diode is applied between a first electrode and the second electrode.

A semiconductor chip includes a semiconductor body having a main surface and a rear surface opposite the main surface, a first bond pad disposed on the main surface, a second bond pad disposed on the rear surface, a first switching device that is monolithically integrated in the semiconductor body and has a first input-output terminal that is electrically connected to the first bond pad, and a second switching device that is monolithically integrated in the semiconductor body and has a first input-output terminal that is electrically connected to the second bond pad.

Embodiments of the disclosure provide an integrated circuit (IC) structure with a diode over a lateral bipolar transistor. A structure according to the disclosure may include a lateral bipolar transistor within a monocrystalline semiconductor over a substrate. An insulator layer is over a portion of the monocrystalline semiconductor. A diode is within a polycrystalline semiconductor on the insulator layer. A cathode of the diode is coupled to a first well within the monocrystalline semiconductor. The first well defines one of an emitter terminal and a collector terminal of the lateral bipolar transistor.

A semiconductor device includes a semiconductor substrate, a top electrode in contact with a top surface of the semiconductor substrate, a bottom electrode in contact with a bottom surface of the semiconductor substrate, and an oxide film in contact with the top surface of the semiconductor substrate. The semiconductor substrate includes an element region and an outer peripheral region. The element region is a region where the top electrode is in contact with the top surface of the semiconductor substrate. The outer peripheral region is a region where the oxide film is in contact with the top surface of the semiconductor substrate, and is located between the element region and an outer peripheral end surface of the semiconductor substrate. The element region includes a semiconductor element connected between the top electrode and the bottom electrode. The outer peripheral region includes surface high-voltage-breakdown regions, deep high-voltage-breakdown regions, and a drift region.

A gate driver integrated circuit for driving a gate of an IGBT or MOSFET receives an input signal. In response to a rising edge of the input signal, the integrated circuit causes the gate to be driven in a first sequence of time periods. In each period, the gate is driven high (pulled up) via a corresponding one of a plurality of different effective gate resistances. In response to a falling edge of the input signal, the integrated circuit causes the gate to be driven in a second sequence of time periods. In each period, the gate is driven low (pulled down) via a corresponding one of the different effective gate resistances. In one example, the duration of each time period is set by a corresponding external passive circuit component. The different effective gate resistances are set by external gate resistors disposed between the integrated circuit and the gate.

A semiconductor package in an embodiment includes a semiconductor device which has a first semiconductor element, a second semiconductor element, and a common first electrode between the first and second semiconductor elements. A second electrode is electrically connected to the first semiconductor element. A third electrode extends through the second semiconductor element and electrically connects to the first electrode. A fourth electrode is electrically connected to the second semiconductor element. A first terminal of the package is electrically connected to the third electrode. A second terminal of the package is electrically connected to the second electrode and the fourth electrode. An insulating material surrounds the semiconductor device.

A semiconductor arrangement is presented. The semiconductor arrangement comprises a semiconductor body, the semiconductor body including a semiconductor drift region, wherein the semiconductor drift region has dopants of a first conductivity type; a first semiconductor sense region and a second semiconductor sense region, wherein each of the first semiconductor sense region and the second semiconductor sense region is electrically connected to the semiconductor drift region and has dopants of a second conductivity type different from said first conductivity type; a first metal contact comprising a first metal material, the first metal contact being in contact with the first semiconductor sense region, wherein a transition between the first metal contact and the first semiconductor sense region forms a first metal-to-semiconductor transition; a second metal contact comprising a second metal material different from said first metal material, the second metal contact being separated from the first metal contact and in contact with the second semiconductor sense region, a transition between the second metal contact and the second semiconductor sense region forming a second metal-to-semiconductor transition different from said first metal-to-semiconductor transition; first electrical transmission means, the first electrical transmission means being arranged and configured for providing a first sense signal derived from an electrical parameter of the first metal contact to a first signal input of a sense signal processing unit; and second electrical transmission means separated from said first electrical transmission means, the second electrical transmission means being arranged and configured for providing a second sense signal derived from an electrical parameter of the second metal contact to a second signal input of said sense signal processing unit.

The subject matter disclosed herein relates to semiconductor power devices, such as silicon carbide (SiC) power devices. In particular, the subject matter disclosed herein relates to shielding regions in the form of channel region extensions for that reduce the electric field present between the well regions of neighboring device cells of a semiconductor device under reverse bias. The disclosed channel region extensions have the same conductivity-type as the channel region and extend outwardly from the channel region and into the JFET region of a first device cell such that a distance between the channel region extension and a region of a neighboring device cell having the same conductivity type is less than or equal to the parallel JFET width. The disclosed shielding regions enable superior performance relative to a conventional stripe device of comparable dimensions, while still providing similar reliability (e.g., long-term, high-temperature stability at reverse bias).

The subject matter disclosed herein relates to semiconductor power devices, such as silicon carbide (SiC) power devices. In particular, the subject matter disclosed herein relates to disconnected or connected shielding regions that reduce the electric field present between the well regions of neighboring device cells of a semiconductor device under reverse bias. The disclosed shielding regions occupy a widest portion of the JFET region between adjacent device cells such that a distance between a shielding region and well regions surrounding device cell is less than a parallel JFET width between two adjacent device cells, while maintaining a channel region width and/or a JFET region density that is greater than that of a comparable conventional stripe device. As such, the disclosed shielding regions and device layouts enable superior performance relative to a conventional stripe device of comparable dimensions, while still providing similar reliability (e.g., long-term, high-temperature stability at reverse bias).

The subject matter disclosed herein relates to silicon carbide (SiC) power devices. In particular, the present disclosure relates to shielding regions for use in combination with an optimization layer. The disclosed shielding regions reduce the electric field present between the well regions of neighboring device cells of a semiconductor device under reverse bias. The disclosed shielding regions occupy a portion of the JFET region between adjacent device cells and interrupt the continuity of the optimization layer in a widest portion of the JFET region, where the corners of neighboring device cells meet. The disclosed shielding regions and device layouts enable superior performance relative to a conventional stripe device of comparable dimensions, while still providing similar reliability (e.g., long-term, high-temperature stability at reverse bias).