Provided is a semiconductor device that includes a first conductivity type well region below a gate runner portion, wherein a diode region includes first contact portions, a first conductivity type anode region, and a second conductivity type cathode region; wherein the well region contacts the diode region in the first direction, and when an end of the well region, an end of at least one of first contact portions, and an end of the cathode region that face one another in the first direction are imaginary projected on an upper surface of the semiconductor substrate, a first distance is longer than a second distance, the first distance being a distance between the end of the well region and the end of the cathode region, and the second distance being a distance between the end of the well region and the end of the at least one first contact portion.

A negative capacitance field effect transistor (NCFET) device is provided. The NCFET device includes a substrate, and a transistor stack structure formed on the substrate. The nanosheet stack structure includes a PFET region and an NFET region, the PFET region including a pWF metal layer stack and the NFET region including a nWF metal layer stack. The NCFET device also includes a dielectric interfacial layer formed on the transistor stack structure, the dielectric interfacial layer including metal induced oxygen vacancies, and the dielectric interfacial layer formed on a portion of the transistor stack structure. The NCFET device also includes a top electrode formed on the dielectric interfacial layer.

According to an embodiment, a semiconductor device includes a first electrically conductive portion, a first semiconductor chip of a reverse-conducting insulated gate bipolar transistor, a second electrically conductive portion, a third electrically conductive portion, a second semiconductor chip of an insulated gate bipolar transistor, and a fourth electrically conductive portion. The first semiconductor chip includes a first electrode and a second electrode. The first electrode is electrically connected to the first electrically conductive portion. The second electrically conductive portion is electrically connected to the second electrode. The third electrically conductive portion is electrically connected to the first electrically conductive portion. The second semiconductor chip includes a third electrode and a fourth electrode. The third electrode is electrically connected to the third electrically conductive portion. The fourth electrically conductive portion is electrically connected to the fourth electrode and the second electrically conductive portion.

A transistor package comprising: a substrate; a first transistor in thermal contact with the substrate, wherein the transistor comprises a gate; the substrate sintered to a heat sink through a sintered layer; an encapsulant that at least partially encapsulates the first transistor; and a Kelvin connection to the transistor gate.

A metal-oxide semiconductor field effect transistor (MOSFET) includes a source region and a drain region of a first conductivity type. The MOSFET additionally include a body region of a second conductivity type, where the body region underlies at least a portion of the source region and the drain region. The MOSFET further includes a buried region of the first conductivity type, where the buried region is disposed between the body region and a substrate, where the buried region is configured to reduce a capacitance between the source region and the drain region in response to an indicated voltage applied between the body region and the buried region.

An integrated circuit is fabricated on a semiconductor substrate. An insulated gate bipolar transistor (IGBT) is formed upon the semiconductor substrate in which the IGBT has an anode terminal, a cathode terminal, and a gate terminal, and a drift region. A diode is also formed on the semiconductor substrate and has an anode terminal and a cathode terminal, in which the anode of the diode is coupled to the anode terminal of the IGBT and the cathode of the diode is coupled to the drift region of the IGBT.

A method for producing a semiconductor device, the method includes, forming, on a substrate made from a semiconductor substance, at least one bipolar junction (BJ) transistor including a first terminal connected to a first well, the first well formed in the substrate and includes a first dopant having a first dopant concentration. At least one non-BJ transistor is formed on the substrate, the non-BJ transistor includes a second terminal connected to a second well, and the second well formed in the substrate and includes a second dopant having a same polarity as the first dopant. The first dopant concentration of the BJ transistor is higher than the second dopant concentration of the non-BJ transistor.

A semiconductor device 100 has a power transistor N1 of vertical structure and a temperature detection element 10a configured to detect abnormal heat generation by the power transistor N1. The power transistor N1 includes a first electrode 208 formed on a first main surface side (front surface side) of a semiconductor substrate 200, a second electrode 209 formed on a second main surface side (rear surface side) of the semiconductor substrate 200, and pads 210a-210f positioned unevenly on the first electrode 208. The temperature detection element 10a is formed at a location of the highest heat generation by the power transistor N1, the location (near the pad 210b where it is easiest for current to be concentrated) being specified using the uneven positioning of the pads 210a-210f.

A semiconductor device contains a Zener-triggered transistor having a Zener diode vertically integrated in a first current node of the Zener-triggered transistor. The first current node includes an n-type semiconductor material contacting a p-type semiconductor material in a substrate. The Zener diode includes an n-type cathode contacting the first current node, and a p-type anode contacting the n-type cathode and contacting the p-type semiconductor material. The semiconductor device may be formed using an implant mask, with an opening for the Zener diode. Boron and arsenic are implanted into the substrate in an area exposed by the opening in the implant mask. The substrate is subsequently heated to diffuse and activate the implanted boron and arsenic. The Zener-triggered transistor may be used in an ESD circuit or a snubber circuit.

A semiconductor device 100 has a power transistor N1 of vertical structure and a temperature detection element 10a configured to detect abnormal heat generation by the power transistor N1. The power transistor N1 includes a first electrode 208 formed on a first main surface side (front surface side) of a semiconductor substrate 200, a second electrode 209 formed on a second main surface side (rear surface side) of the semiconductor substrate 200, and pads 210a-210f positioned unevenly on the first electrode 208. The temperature detection element 10a is formed at a location of the highest heat generation by the power transistor N1, the location (near the pad 210b where it is easiest for current to be concentrated) being specified using the uneven positioning of the pads 210a-210f.