The present invention provides semiconductor devices with super junction drift regions that are capable of blocking voltage. A super junction drift region is an epitaxial semiconductor layer located between a top electrode and a bottom electrode of the semiconductor device. The super junction drift region includes a plurality of pillars having P type conductivity, formed in the super junction drift region, which are surrounded by an N type material of the super junction drift region.

The present disclosure provides an electronic device that includes a substrate. The substrate includes a well and a peripheral insulating wall laterally surrounding the well. At least one lateral bipolar transistor is formed in the well, and the at least one transistor has a base region extending under parallel collector and emitter regions. The peripheral insulating wall is widened in a first direction, parallel to the collector and emitter regions, so that the base region penetrates into the peripheral insulating wall.

A varactor transistor includes a semiconductor fin having a first conductivity type, a plurality of gate structures separated from each other and surrounding a portion of the semiconductor fin. The plurality of gates structures include a dummy gate structure on an edge of the semiconductor fin, and a first gate structure spaced apart from the dummy gate structure. The dummy gate structure and the gate structure each include a gate insulator layer on a surface portion of the semiconductor fin, a gate on the gate insulator layer, and a spacer on the gate. The varactor transistor also includes a raised source/drain region on the semiconductor fin and between the dummy gate structure and the first gate structure, the raised source/drain region and the gate of the dummy gate structure being electrically connected to a same potential.

In one embodiment, the semiconductor devices relate to using one or more super-junction trenches for termination.

A semiconductor device includes an anode doping region of a diode structure arranged in a semiconductor substrate. The anode doping region has a first conductivity type. The semiconductor device further includes a second conductivity type contact doping region having a second conductivity type. The second conductivity type contact doping region is arranged at a surface of the semiconductor substrate and surrounded in the semiconductor substrate by the anode doping region. The anode doping region includes a buried non-depletable portion. At least part of the buried non-depletable portion is located below the second conductivity type contact doping region in the semiconductor substrate.

A Schottky barrier diode according to an exemplary embodiment of the present disclosure includes: an n− type layer disposed on a first surface of an n+ type silicon carbide substrate; a p+ type region and a p type region disposed on the n− type layer and separated from each other; an anode disposed on the n− type layer, the p+ type region, and the p type region; and a cathode disposed on a second surface of the n+ type silicon carbide substrate, wherein the p type region is in plural, has a hexagonal shape on the plane, and is arranged in a matrix shape, and the n− type layer disposed between the p+ type region and the p type region has a hexagonal shape on the plane and encloses the p type region.

The Rds*Cgd figure of merit (FOM) of a laterally diffused metal oxide semiconductor (LDMOS) transistor is improved by forming the drain drift region with a number of dopant implants at a number of depths, and forming a step-shaped back gate region with a number of dopant implants at a number of depths to adjoin the drain drift region.

A method of processing a power diode includes: creating an anode region and a drift region in a semiconductor body; and forming, by a single ion implantation processing step, each of an anode contact zone and an anode damage zone in the anode region. Power diodes manufactured by the method are also described.

The present application discloses a super junction device, comprising: an N-type redundant epitaxial layer and an N-type buffer layer sequentially formed on an N-type semiconductor substrate; wherein a trench-filling super junction structure is formed on the N-type buffer layer; a backside structure of the super junction device comprises a drain region; the N-type semiconductor substrate is removed in a backside thinning process, and the N-type redundant epitaxial layer is completely or partially removed in the backside thinning process; the resistivity of the N-type semiconductor substrate is 0.1-10 times the resistivity of a top epitaxial layer; the resistivity of the N-type redundant epitaxial layer is 0.1-10 times the resistivity of the N-type semiconductor substrate, and the resistivity of the N-type redundant epitaxial layer is lower than the resistivity of the N-type buffer layer. The present application further discloses a method for manufacturing a super junction device.

A semiconductor device has an impurity region covering a bottom of a gate trench and a column region. A bottom of the column region is deeper than a bottom of the gate trench. The impurity region is arranged between the gate trench and the column region. This structure can improve the characteristics of the semiconductor device.