A semiconductor device includes an N+ type substrate, an N type layer disposed on a first surface of the N+ type substrate and having a trench opened to a surface opposite to the surface facing the N+ type substrate, a P type region disposed in the N type layer and disposed on a side surface of the trench, a gate electrode disposed in the trench, and a source electrode and a drain electrode insulated from the gate electrode. The N type layer includes a P type shield region covering a bottom surface and an edge of the trench.

Disclosed herein are lateral gate material arrangements for quantum dot devices, as well as related computing devices and methods. For example, in some embodiments, a quantum dot device may include: a quantum well stack; and a gate above the quantum well stack, wherein the gate includes a gate electrode, the gate electrode includes a first material proximate to side faces of the gate and a second material proximate to a center of the gate, and the first material has a different material composition than the second material.

A HEMT comprising a channel layer of a first III-Nitride semiconductor material, grown on a N-polar surface of a back barrier layer of a second III-Nitride semiconductor material; the second III-Nitride semiconductor material having a larger band gap than the first III-Nitride semiconductor material, such that a positively charged polarization interface and two-dimensional electron gas is obtained in the channel layer; a passivation, capping layer, of said first III-Nitride semiconductor material, formed on top of and in contact with a first portion of a N-polar surface of said channel layer; a gate trench traversing the passivation, capping layer, and ending at said N-polar surface of said channel layer; and a gate conductor filling said gate trench.

Devices and methods for layout-dependent voltage handling improvement in switch stacks. In some embodiments, a switching device can include a first terminal and a second terminal, a radio-frequency signal path implemented between the first terminal and the second terminal, and a plurality of switching elements connected in series to form a stack between the second terminal and ground. The stack can have an orientation relative to the radio-frequency signal path, and the switching elements can have a non-uniform distribution of a first parameter based in part on the orientation of the stack.

A high voltage superjunction MOSFET includes a semiconductor substrate and a semiconductor layer having columns of first and second conductivity. A buffer layer of the first conductivity is between the semiconductor substrate and semiconductor layer. A plug region of the second conductivity is formed at a semiconductor layer surface and extends to the columns. A source/drain region is formed at the semiconductor layer surface and is connected to the plug region. The source/drain region has a concentration of the first conductivity between about 110.sup.19 cm.sup.3 and 1.510.sup.20 cm.sup.3. A body region of the second conductivity is between the source/drain region and the first column and is connected to the plug region. A gate trench is formed in the semiconductor layer surface and extends toward the first column and has a trench gate electrode disposed therein. A dielectric layer separates the trench gate electrode from the first column.

A transistor can include a substrate, an epitaxial oxide layer on the substrate, and a gate layer. The substrate can include a first crystalline material. The epitaxial oxide layer can include a second oxide material including: Li and one of Ni, Al, Ga, Mg, Zn and Ge; or Ni and one of Li, Al, Ga, Mg, Zn and Ge; or Mg and one of Ni, Al, Ga, and Ge; or Zn and one of Ni, Al, Ga, and Ge. The gate layer can include a third oxide material. A bandgap of the third oxide material of the gate can be wider than a bandgap of the second oxide material of the epitaxial oxide layer. The transistor can also include a source electrical contact coupled to the epitaxial oxide layer, a drain electrical contact coupled to the epitaxial oxide layer, and a first gate electrical contact coupled to the gate layer.

A semiconductor device includes a first-conductivity-type drift region provided in a semiconductor substrate; a trench portion provided from an upper surface of the semiconductor substrate to an inside of the semiconductor substrate, and extending in a predetermined extending direction in a plane of the upper surface of the semiconductor substrate; a mesa portion provided in contact with the trench portion in an array direction orthogonal to the extending direction; a second-conductivity-type base region provided in the mesa portion above the drift region and in contact with the trench portion; and a second-conductivity-type floating region provided in the mesa portion below the base region, in contact with the trench portion, and provided in at least a part of the mesa portion in the array direction.

According to one embodiment, a semiconductor device includes a first electrode, a first semiconductor region of a first conductivity type, a second electrode, a gate electrode, second semiconductor regions of a second conductivity type, third semiconductor regions of the first conductivity type, and a third electrode. The second electrode is provided in a plurality in second and third directions. Each second electrode opposes a portion of the first semiconductor region in the second and third directions with an insulating layer interposed. The gate electrode is provided around each second electrode. The first semiconductor region includes first regions provided respectively around the second electrodes and the second region provided around the first regions in the second and third directions. Impurity concentration of the first conductivity type in each of the first regions is higher than impurity concentration of the first conductivity type in the second region.

A semiconductor device according to an embodiment of the present disclosure includes: a conductive region, an end region positioned at a portion where the conductive region ends, and a connection region positioned between the conductive region and the end region. The conductive region includes: an n+ type substrate; an n type layer positioned at the first surface of the n+ type substrate; and a p type region positioned on the n type layer, and a gate electrode that fills an inside of a trench penetrating the p type region and positioned in the n type layer, and a side wall of the trench positioned at the portion where the conductive region ends is inclined.

An apparatus includes a drain and a source on opposing sides of an epitaxial layer, a plurality of gates formed in the epitaxial layer, a source contact connected to the source, a gate contact connected to the plurality of gates, a drain contact on opposing sides of the epitaxial layer of the source contact, a gate-source electrostatic discharge (ESD) diode connected between the gate contact and the source contact, and a breakdown voltage enhancement and leakage prevention structure formed underneath the gate-source ESD diode structure, wherein the breakdown voltage enhancement and leakage prevention structure comprises a body ring structure.