A technique of suppressing leak current in a semiconductor device is provided. A semiconductor device, comprises: a semiconductor layer made of a semiconductor; an insulating layer configured to have electric insulation property and formed to cover part of the semiconductor layer; a first electrode layer formed on the semiconductor layer, configured to have a work function of not less than 0.5 eV relative to electron affinity of the semiconductor layer and extended to surface of the insulating layer to form a field plate structure; and a second electrode layer configured to have electrical conductivity and formed to cover at least part of the first electrode layer. A distance between an edge of a part of the first electrode layer that is in contact with the semiconductor layer and the second electrode layer is equal to or greater than 0.2 m.

Production of an integrated circuit including an electrical contact on SiC is disclosed. One embodiment provides for production of an electrical contact on an SiC substrate, in which a conductive contact is produced on a boundary surface of the SiC substrate by irradiation and absorption of a laser pulse on an SiC substrate.

A semiconductor device according to an embodiment includes an n-type SiC region, an electrode in contact with the SiC region, and a region including oxygen, the region provided in the SiC region, the region being provided on an electrode side of the SiC region.

Semiconductor devices are formed using a thin epitaxial layer (nanotube) formed on sidewalls of dielectric-filled trenches. In one embodiment, a method for forming a semiconductor device includes forming a first epitaxial layer on sidewalls of trenches and forming second epitaxial layer on the first epitaxial layer where charges in the doped regions along the sidewalls of the first and second trenches achieve charge balance in operation. In another embodiment, the semiconductor device includes a termination structure including an array of termination cells.

One embodiment of the disclosure relates to an unguarded Schottky barrier diode. The diode includes a cathode that has a recessed region and a dielectric interface surface that laterally extends around a perimeter of the recessed region. The diode further includes an anode that conforms to the recessed region. A dielectric layer extends over the dielectric interface surface of the cathode and further extends over a portion of the anode near the perimeter. Other devices and methods are also disclosed.

Generally discussed herein are techniques for and systems and apparatuses configured to control phonons using an electric field. In one or more embodiments, an apparatus can include electrical contacts, two quantum dots embedded in a semiconductor such that when an electrical bias is applied to the electrical contacts, the electric field produced by the electrical bias is substantially parallel to an axis through the two quantum dots, and a phononic wave guide coupled to the semiconductor, the phononic wave guide configured to transport phonons therethrough.

A method of forming a semiconductor device and a semiconductor device are provided. The method includes providing a wafer stack including a carrier wafer comprising graphite and a device wafer comprising a wide band-gap semiconductor material and having a first side and a second side opposite the first side, the second side being attached to the carrier wafer, defining device regions of the wafer stack, partly removing the carrier wafer so that openings are formed in the carrier wafer arranged within respective device regions and that the device wafer is supported by a residual of the carrier wafer; and further processing the device wafer while the device wafer remains supported by the residual of the carrier wafer.

A semiconductor device including a terminal region that can suppress a resist collapse in manufacturing and effectively relieve a concentration of electric fields and a method for manufacturing the semiconductor device. The semiconductor device includes a semiconductor element formed in a semiconductor substrate made of a silicon carbide semiconductor of a first conductivity type and a plurality of ring-shaped regions of a second conductivity type formed in the semiconductor substrate while surrounding the semiconductor element in plan view. At least one of the plurality of ring-shaped regions includes one or more separation regions of the first conductivity type that cause areas of the first conductivity type on an inner side and an outer side of one of the ring-shaped regions to communicate with each other in plan view.

Methods for forming a fin-based RF diode with improved performance characteristics and the resulting devices are disclosed. Embodiments include forming fins over a substrate, separated from each other, each fin having a lower portion and an upper portion; forming STI regions over the substrate, between the lower portions of adjacent fins; implanting the lower portion of each fin with a first-type dopant; implanting the upper portion of each fin, above the STI region, with the first-type dopant; forming a junction region around a depletion region and along exposed sidewalls and a top surface of the upper portion of each fin; and forming a contact on exposed sidewalls and a top surface of each junction region.

A charge-balanced (CB) diode may include one or more CB layers. Each CB layer may include an epitaxial layer having a first conductivity type and a plurality of buried regions having a second conductivity type. Additionally, the CB diode may include an upper epitaxial layer having the first conductivity type that is disposed adjacent to an uppermost CB layer of the one or more CB layers. The upper epitaxial layer may also include a plurality of junction barrier (JBS) implanted regions having the second conductivity type. Further, the CB diode may include a Schottky contact disposed adjacent to the upper epitaxial layer and the plurality of JBS implanted regions.