The present invention provides a semiconductor device that prevents destruction due to an avalanche breakdown and that has a high tolerance against breakdown by configuring the device so as to have a punch-through breakdown function therein and such that the breakdown voltage of a punch-through breakdown is lower than an avalanche breakdown voltage so that an avalanche breakdown does not occur.

A semiconductor device and manufacturing method achieve miniaturization, prevent rise in threshold voltage and on-state voltage, and prevent decrease in breakdown resistance. N.sup.+-type emitter region and p.sup.++-type contact region are repeatedly alternately disposed in a first direction in which a trench extends in stripe form in a mesa portion sandwiched between trench gates. P.sup.+-type region covers an end portion on lower side of junction interface between n.sup.+-type emitter region and p.sup.++-type contact region. Formation of trench gate structure is such that n.sup.+-type emitter region is selectively formed at predetermined intervals in the first direction in the mesa portion by first ion implantation. P.sup.+-type region is formed less deeply than n.sup.+-type emitter region in the entire mesa portion by second ion implantation. The p.sup.++-type contact region is selectively formed inside the p+-type region by third ion implantation. N.sup.+-type emitter region and p.sup.++-type contact region are diffused and brought into contact.

This disclosure relates to a novel approach towards enhancing the threshold voltage of an enhancement-mode field-effect-transistor (E-mode FET) using doped or polarization-graded buffer layers and utilizing drain-connected field plates to engineer peak fields. Enhancement-mode field effect transistors (E-mode FETs) with doped buffer layers replacing conventional undoped buffer layers could enable larger threshold voltages, owing to higher capacitance from the back. These FETs with larger threshold voltages, however, would experience large operational electric fields near the drain contact. Described herein are embodiments of an E-mode FET further comprised of doped buffer layer(s) in the structure of the HEMT to enable larger positive threshold voltages, with optional one or more drain field plates that modify the electric field profile in the channel of the device and improve device breakdown characteristics.

A method of controlling an etch-pattern density of a polysilicon layer includes depositing polysilicon on a wafer. The method includes determining polysilicon-etch regions that include DMOS source regions within circuit-device areas of the wafer. The method includes calculating an etch area of the polysilicon-etch regions and then comparing the calculated etch area of the polysilicon-etch regions to a predetermined minimum etch area. If the calculated etch area is less than a predetermined threshold, the method adds polysilicon-etch regions within non-circuit-device areas to the determined polysilicon-etch regions within the circuit-device areas until the comparing step results in the calculated etch area of the polysilicon-etch regions being greater than the predetermined minimum etch area. The method includes etching the polysilicon from the polysilicon-etch regions in both the circuit-device areas and the non-circuit-device areas. Adding polysilicon-etch regions in non-circuit device areas can advantageously facilitate automatic process control of an etch step.

A semiconductor device for electrostatic discharge (ESD) protection including a source, a gate, a drain having a drain diffusion, and a diffusion region extending from, or located under, the drain diffusion. The source, the gate, the drain and the diffusion region are located in or on a substrate. The diffusion region is laterally spaced from at least one of the gate or the outer edge of the drain diffusion.

A semiconductor device includes: an IGBT section including a vertical IGBT; and a diode section arranged along the IGBT section and including a diode. The diode section includes a hole injection reduction layer having a first conductivity type and arranged in an upper layer portion of a drift layer, extending to a depth deeper than an anode region constituted by a second conductivity type region in the diode section, having an impurity concentration lower than an impurity concentration of the anode region and higher than an impurity concentration of the drift layer.

Embodiments of the invention include a method for fabricating a nano-ribbon transistor device and the resulting structure. A nano-ribbon transistor device including a substrate, a nano-ribbon channel, a core region in the center of the nano-ribbon channel, a gate formed around the nano-ribbon channel, a spacer formed on each sidewall of the gate, and a source and drain region epitaxially formed adjacent to each spacer is provided. The core region in the center of the nano-ribbon channel is selectively etched. A dielectric material is deposited on the exposed portions of the nano-ribbon channel. A back-bias control region is formed on the dielectric material within the core of the nano-ribbon channel and on the substrate adjacent to the nano-ribbon transistor device. A metal contact is formed in the back-bias control region.

Semiconductor devices and methods of fabricating such devices are provided. The devices include source and drain regions on one conductivity type separated by a channel length and a gate structure. The devices also include a channel region of the one conductivity type formed in the device region between the source and drain regions and a screening region of another conductivity type formed below the channel region and between the source and drain regions. In operation, the channel region forms, in response to a bias voltage at the gate structure, a surface depletion region below the gate structure, a buried depletion region at an interface of the channel region and the screening region, and a buried channel region between the surface depletion region and the buried depletion region, where the buried depletion region is substantially located in channel region.

A semiconductor device includes a substrate having a first conductivity type, a high-voltage well having a second conductivity type and disposed in the substrate, a source region disposed in the high-voltage well, a drain region disposed in the high-voltage well and spaced apart from the source region along a first direction, and a buried layer having the second conductivity type and disposed under an area between the source region and the drain region.

A semiconductor die that may include a substrate; an epitaxial layer; a metal layer; a first transistor; and a metal via that surrounds the first transistor, extends between the metal layer and the substrate, and penetrates the substrate.