In some embodiments, a semiconductor structure can include: a diamond substrate having a surface conductive layer; a heavily doped region formed in the diamond substrate; and a metal contact positioned over the conductive surface layer such that a first portion of the heavily doped region is covered by the metal contact and a second portion of the heavily doped region is not covered by the metal contact.

Disclosed herein is a new and improved system and method for fabricating monolithically integrated diamond semiconductor. The method may include the steps of seeding the surface of a substrate material, forming a diamond layer upon the surface of the substrate material; and forming a semiconductor layer within the diamond layer, wherein the diamond semiconductor of the semiconductor layer has n-type donor atoms and a diamond lattice, wherein the donor atoms contribute conduction electrons with mobility greater than 770 cm.sup.2/Vs to the diamond lattice at 100 kPa and 300K, and Wherein the n-type donor atoms are introduced to the lattice through ion tracks.

In this method for manufacturing a semiconductor element, a modified layer produced by subjecting a substrate (70) to mechanical polishing is removed by heating the substrate (70) under Si vapor pressure. An epitaxial layer formation step, an ion implantation step, an ion activation step, and a second removal step are then performed. In the second removal step, macro-step bunching and insufficient ion-implanted portions of the surface of the substrate (70) performed the ion activation step are removed by heating the substrate (70) under Si vapor pressure. After that, an electrode formation step in which electrodes are formed on the substrate (70) is performed.

A silicon carbide substrate has a trench extending from a main surface of the silicon carbide substrate into the silicon carbide substrate. The trench has a trench width at a trench bottom. A shielding region is formed in the silicon carbide substrate. The shielding region extends along the trench bottom. In at least one doping plane extending approximately parallel to the trench bottom, a dopant concentration in the shielding region over a lateral first width deviates by not more than 10% from a maximum value of the dopant concentration. The first width is less than the trench width and is at least 30% of the trench width.

Devices and methods of a field effect transistor device that include a source, a gate and a drain. The transistor includes a semiconductor region position is under the source, the gate and the drain. Such that the semiconductor region can include a gallium nitride (GaN) layer and an III Nitride (III-N) layer. Wherein the GaN layer includes a band gap, and the III-N layer includes a band gap. Such that the III-N layer band gap is higher than the GaN layer band gap. A sub-region of the semiconductor region is located underneath the gate and is doped with Mg ions at selective locations in the sub-region.

A method includes forming a hard mask over an epitaxy layer of a substrate; forming a patterned mask over the hard mask; etching the hard mask and the epitaxy layer to form a trench in the epitaxy layer, in which a remaining portion of the hard mask covers a topmost surface of the epitaxy layer, and the trench exposes a sidewall of the epitaxy layer; forming a P-well region by directing p-type ion beams into the trench along an oblique direction that is non-parallel to a normal line of the topmost surface of the epitaxy layer, in which the topmost surface of the epitaxy layer is protected from the p-type ion beams by the remaining portion of the hard mask during directing the p-type ion beams into the trench; and after directing the p-type ion beams into the trench, forming a gate structure in the trench.

Disclosed herein is a new and improved system and method for fabricating diamond semiconductors. The method may include the steps of selecting a diamond semiconductor material having a surface, exposing the surface to a source gas in an etching chamber, forming a carbide interface contact layer on the surface; and forming a metal layer on the interface layer.

A system and method for optimizing a ribbon ion beam in a beam line implantation system is disclosed. The system includes a mass resolving apparatus having a resolving aperture, in which the resolving aperture may be moved in the X and Z directions. Additionally, a controller is able to manipulate the mass analyzer and quadrupole lenses so that the crossover point of desired ions can also be moved in the X and Z directions. By manipulating the crossover point and the resolving aperture, the parameters of the ribbon ion beam may be manipulated to achieve a desired result. Movement of the crossover point in the X direction may affect the mean horizontal angle of the beamlets, while movement of the crossover point in the Z direction may affect the horizontal angular spread and beam current.

Some embodiments of the disclosure provide a method for forming a semiconductor device. The method includes: forming a plurality of semiconductor material layers on a doped substrate; removing a part of the plurality of semiconductor material layers to form an exposed doped substrate; and ion implanting a dopant into the exposed doped substrate to form a doped semiconductor structure, where the doped substrate and the doped semiconductor structure have different polarities.

An integrated circuit includes a junction field-effect transistor formed in a semiconductor substrate. The junction field-effect transistor includes a drain region, a source region, a channel region, and a gate region. A first isolating region separates the drain region from both the gate region and the channel region. A first connection region connects the drain region to the channel region by passing underneath the first isolating region in the semiconductor substrate. A second isolating region separates the source region from both the gate region and the channel region. A second connection region connects the source region to the channel region by passing underneath the second isolating region in the semiconductor substrate.