A semiconductor device includes a chip that includes a mounting surface, a non-mounting surface, and a side wall connecting the mounting surface and the non-mounting surface and has an eaves portion protruding further outward than the mounting surface at the side wall and a metal layer that covers the mounting surface.

A semiconductor device includes an electrical device and has an output capacitance characteristic with at least one output capacitance maximum located at a voltage larger than 5% of a breakdown voltage of the semiconductor device. The output capacitance maximum is larger than 1.2 times an output capacitance at an output capacitance minimum located at a voltage between the voltage at the output capacitance maximum and 5% of a breakdown voltage of the semiconductor device.

The disclosure relates to a semiconductor die with a transistor device, having a source region, a drain region, a body region including a channel region, a gate region, which includes a gate electrode, next to the channel region, for controlling a channel formation, a drift region between the channel region and the drain region, and a field electrode region with a field electrode formed in a field electrode trench, which extends into the drift region, wherein the channel region extends laterally and is aligned vertically with the gate region, and wherein at least a portion of the channel region is arranged vertically above the field electrode region.

The disclosure relates to a semiconductor die, including a vertical power transistor device, a pull-down transistor device, and a capacitor. The pull-down transistor device is connected between a gate electrode of the vertical power transistor device and a ground terminal and connects the gate electrode to the ground terminal in a conducting state. The capacitor is connected between one of the load terminals of the vertical power transistor device and the control terminal of the pull-down transistor device and capacitively couples the one load terminal to the control terminal.

A semiconductor device (300) comprising: a doped semiconductor substrate (302); an epitaxial layer (304), disposed on top of the substrate, the epitaxial layer having a lower concentration of dopant than the substrate; a switching region disposed on top of the epitaxial layer; and a contact diffusion (350) disposed on top of the epitaxial layer, the contact diffusion having a higher concentration of dopant than the epitaxial layer; wherein the epitaxial layer forms a barrier between the contact diffusion and the substrate.

A method for forming a superjunction power semiconductor device includes forming multiple epitaxial layers of a first conductivity type on a semiconductor substrate and implanting dopants of a second conductivity type into each epitaxial layer to form a first group of implanted regions in a first region and a second group of implanted regions in a second region in each epitaxial layer. The multiple epitaxial layers are annealed to form multiple columns of the second conductivity type having slanted sidewalls across the first to last epitaxial layers. The columns include a first group of columns formed by the implanted regions of the first group and having a first grading and a second group of columns formed by the implanted regions of the second group and having a second grading, where the second grading is less than the first grading.

A super-junction device and a method of fabricating such a device are disclosed, in which a pillar of a second conductivity type situated at an interface between a transition region and a core region is narrowed in width across at least an upper thickness thereof, thereby reducing peak electric field strength in the transition region, increasing voltage endurance of the transition region and preventing the occurrence of avalanche breakdown first in the transition region. Additionally, a dopant ion concentration profile increasing in the direction from the transition region to the core region is created across upper portions of some pillars of the second conductivity type in the core region, which increases the presence of the dopant of the second conductivity type around the surface of the core region and thus stops a vertical electric field before it can reach wells of the second conductivity type. That is, an effective epitaxial thickness of the core region is reduced, which results in lower voltage endurance thereof. In this way, it is ensured that avalanche breakdown occurs first in the core region, resulting in improved EAS performance.

A semiconductor device having a super junction and a method of manufacturing the semiconductor device capable of obtaining a high breakdown voltage are provided, whereby charge balance of the super junction is further accurately controlled in the semiconductor device that is implemented by an N-type pillar and a P-type pillar. The semiconductor device includes a semiconductor substrate; and a blocking layer including a first conductive type pillar and a second conductive type pillar that extend in a vertical direction on the semiconductor substrate and that are alternately arrayed in a horizontal direction, wherein, in the blocking layer, a density profile of a first conductive type dopant may be uniform in the horizontal direction, and the density profile of the first conductive type dopant may vary in the vertical direction.

Disclosed is a superjunction semiconductor device and a method for manufacturing the same and, more particularly, to a superjunction semiconductor device and a method for manufacturing the same seeking to improve on-resistance characteristics of the device without degrading breakdown voltage characteristics by forming a second conductivity type impurity region on and/or in a surface of a substrate in a cell region C to increase a second conductivity type impurity concentration in the device.

A semiconductor structure and a method of forming the same are provided. In an embodiment, a semiconductor structure includes an epitaxial source feature and an epitaxial drain feature, a vertical stack of channel members disposed over a backside dielectric layer, the vertical stack of channel members extending between the epitaxial source feature and the epitaxial drain feature along a direction, a gate structure wrapping around each of the vertical stack of channel members, and a backside source contact disposed in the backside dielectric layer. The backside source contact includes a top portion adjacent the epitaxial source feature and a bottom portion away from the epitaxial source feature. The top portion and the bottom portion includes a step width change along the direction.