Abstract: An apparatus includes a substrate. The apparatus further includes a group III-nitride buffer layer on the substrate; a group III-nitride barrier layer on the group III-nitride buffer layer, the group III-nitride barrier layer including a higher bandgap than a bandgap of the group III-nitride buffer layer. The apparatus further includes a source electrically coupled to the group III-nitride barrier layer; a gate electrically coupled to the group III-nitride barrier layer; a drain electrically coupled to the group III-nitride barrier layer; and a p-region being at least one of the following: in the substrate or on the substrate below said group III-nitride barrier layer.

Abstract: An apparatus includes a substrate. The apparatus further includes a group III-nitride buffer layer on the substrate; a group III-nitride barrier layer on the group III-nitride buffer layer, the group III-nitride barrier layer including a higher bandgap than a bandgap of the group III-nitride buffer layer. The apparatus further includes a source electrically coupled to the group III-nitride barrier layer; a gate electrically coupled to the group III-nitride barrier layer; a drain electrically coupled to the group III-nitride barrier layer; and a p-region being at least one of the following: in the substrate or on the substrate below said group III-nitride barrier layer.

Abstract: An apparatus includes a substrate. The apparatus further includes a group III-nitride buffer layer on the substrate; a group III-nitride barrier layer on the group III-nitride buffer layer, the group III-nitride barrier layer including a higher bandgap than a bandgap of the group III-nitride buffer layer. The apparatus further includes a source electrically coupled to the group III-nitride barrier layer; a gate electrically coupled to the group III-nitride barrier layer; a drain electrically coupled to the group III-nitride barrier layer; and a p-region being at least one of the following: in the substrate or on the substrate below said group III-nitride barrier layer.

Abstract: The wafer fabrication technique uses an ion implantation process on the back side of the wafer to control the shape of the wafer. At least one first dopant is implanted into a front side of a wafer to dope the wafer. At least one second dopant is implanted into a back side of the wafer in a dopant profile to create a back side structure, where the back side structure controls a shape of the wafer. A blank wafer is provided that has an undoped front side and a form shaping back side structure on the back side. A doped wafer is provided that has a dopant implanted on the front side and a form shaping back side structure on the back side that least partially offsets the strain in the wafer induced by the front side dopant.

Abstract: An apparatus includes a substrate. The apparatus further includes a group III-nitride buffer layer on the substrate; a group III-nitride barrier layer on the group III-nitride buffer layer, the group III-nitride barrier layer including a higher bandgap than a bandgap of the group III-nitride buffer layer. The apparatus further includes a source electrically coupled to the group III-nitride barrier layer; a gate electrically coupled to the group III-nitride barrier layer; a drain electrically coupled to the group III-nitride barrier layer; and a p-region being at least one of the following: in the substrate or on the substrate below said group III-nitride barrier layer.

Abstract: The wafer fabrication technique uses an ion implantation process on the back side of the wafer to control the shape of the wafer. At least one first dopant is implanted into a front side of a wafer to dope the wafer. At least one second dopant is implanted into a back side of the wafer in a dopant profile to create a back side structure, where the back side structure controls a shape of the wafer. A blank wafer is provided that has an undoped front side and a form shaping back side structure on the back side. A doped wafer is provided that has a dopant implanted on the front side and a form shaping back side structure on the back side that least partially offsets the strain in the wafer induced by the front side dopant.

Abstract: The disclosure is directed to a high-electron mobility transistor that includes a SiC substrate layer, a GaN buffer layer arranged on the SiC substrate layer, and a p-type material layer having a length parallel to a surface of the SiC substrate layer over which the GaN buffer layer is provided. The p-type material layer is provided in one of the following: the SiC substrate layer and a first layer arranged on the SiC substrate layer. A method of making the high-electron mobility transistor is also disclosed.

Abstract: The wafer fabrication technique uses an ion implantation process on the back side of the wafer to control the shape of the wafer. At least one first dopant is implanted into a front side of a wafer to dope the wafer. At least one second dopant is implanted into a back side of the wafer in a dopant profile to create a back side structure, where the back side structure controls a shape of the wafer. A blank wafer is provided that has an undoped front side and a form shaping back side structure on the back side. A doped wafer is provided that has a dopant implanted on the front side and a form shaping back side structure on the back side that least partially offsets the strain in the wafer induced by the front side dopant.

Abstract: A semiconductor die and a process for fabricating the semiconductor die are disclosed. The semiconductor die has a substrate and a silicon carbide (SiC) epitaxial structure on the substrate. The SiC epitaxial structure includes at least a first N-type SiC layer, at least a first P-type SiC layer, and carbon vacancy reduction material, which has been implanted into a surface of the SiC epitaxial structure. Further, the SiC epitaxial structure has been annealed to mobilize the carbon vacancy reduction material to diffuse carbon atoms substantially throughout the SiC epitaxial structure, thereby increasing an average carrier lifetime in the SiC epitaxial structure.

Abstract: An apparatus includes a substrate. The apparatus further includes a group III-nitride buffer layer on the substrate; a group III-nitride barrier layer on the group III-nitride buffer layer, the group III-nitride barrier layer including a higher bandgap than a bandgap of the group III-nitride buffer layer. The apparatus further includes a source electrically coupled to the group III-nitride barrier layer; a gate electrically coupled to the group III-nitride barrier layer; a drain electrically coupled to the group III-nitride barrier layer; and a p-region being at least one of the following: in the substrate or on the substrate below said group III-nitride barrier layer.

Abstract: The disclosure is directed to a high-electron mobility transistor that includes a SiC substrate layer, a GaN buffer layer arranged on the SiC substrate layer, and a p-type material layer having a length parallel to a surface of the SiC substrate layer over which the GaN buffer layer is provided. The p-type material layer is provided in one of the following: the SiC substrate layer and a first layer arranged on the SiC substrate layer. A method of making the high-electron mobility transistor is also disclosed.

Abstract: A Schottky diode includes a drift region doped with dopants having a first conductivity type, first and second blocking junctions that are doped with dopants having a second conductivity type in an upper portion of the drift region, first and second local current spreading layers doped with dopants having the first conductivity type underneath the respective first and second blocking junctions, and first and second contacts on respective lower and upper portions of the drift region. A channel is provided in the upper portion of the drift region between the first and second blocking junctions, the channel doped with dopants having the first conductivity type and a concentration of dopants in at least a first portion of the channel being lower than the concentration of dopants in the first and second local current spreading layers.

Abstract: The disclosure is directed to a high-electron mobility transistor that includes a SiC substrate layer, a GaN buffer layer arranged on the SiC substrate layer, and a p-type material layer having a length parallel to a surface of the SiC substrate layer over which the GaN buffer layer is provided. The p-type material layer is provided in one of the following: the SiC substrate layer and a first layer arranged on the SiC substrate layer. A method of making the high-electron mobility transistor is also disclosed.

Abstract: A method of fabricating a semiconductor device includes selecting an element for implanting into a substrate. The element has at least a first isotope and a second isotope. At least one implant contaminant is identified as having a particle weight that is substantially identical to an atomic weight of the first isotope of the element. As such, ions of the second isotope of the element are selectively implanted into a region of the substrate. The second isotope has an atomic weight that is different from the particle weight of the at least one implant contaminant. For example, the selected element may be silicon (Si), the implant contaminant may be nitrogen (N2), the first isotope having the substantially identical atomic weight may be silicon-28, and the second isotope having the different atomic weight may be silicon-29. Related methods, apparatus, and devices are also discussed.

Abstract: A method is disclosed for treating a silicon carbide substrate for improved epitaxial deposition thereon and for use as a precursor in the manufacture of devices such as light emitting diodes. The method includes the steps of implanting dopant atoms of a first conductivity type into the first surface of a conductive silicon carbide wafer having the same conductivity type as the implanting ions at one or more predetermined dopant concentrations and implant energies to form a dopant profile, annealing the implanted wafer, and growing an epitaxial layer on the implanted first surface of the wafer.

Abstract: A method of growing polygonal carbon from photoresist and resulting structures are disclosed. Embodiments of the invention provide a way to produce polygonal carbon, such as graphene, by energizing semiconductor photoresist. The polygonal carbon can then be used for conductive paths in a finished semiconductor device, to replace the channel layers in MOSFET devices on a silicon carbide base, or any other purpose for which graphene or graphene-like carbon material formed on a substrate is suited. In some embodiments, the photoresist layer forms both the polygonal carbon layer and an amorphous carbon layer over the polygonal carbon layer, and the amorphous carbon layer is removed to leave the polygonal carbon on the substrate.

Abstract: A MESFET includes a silicon carbide layer, spaced apart source and drain regions in the silicon carbide layer, a channel region positioned within the silicon carbide layer between the source and drain regions and doped with implanted dopants, and a gate contact on the silicon carbide layer. Methods of forming a MESFET include providing a layer of silicon carbide, forming spaced apart source and drain regions in the silicon carbide layer, implanting impurity atoms to form a channel region between the source and drain regions, annealing the implanted impurity atoms, and forming a gate contact on the silicon carbide layer.

Abstract: A semiconductor device fabrication apparatus includes a load lock chamber, a loading assembly in the load lock chamber, and an ion implantation target chamber that is hermetically connected to the load lock chamber. The load lock chamber is configured to store a plurality of wafer plates. Each wafer plate respectively includes at least one semiconductor wafer thereon. The ion implantation target chamber is configured to implant an ion species into a semiconductor wafer on a currently loaded wafer plate. The loading assembly is also configured to load a next one of the plurality of wafer plates from the load lock chamber into the ion implantation target chamber. The loading assembly may be configured to load the next wafer plate from the load lock chamber into the ion implantation target chamber while substantially maintaining a current temperature within the ion implantation target chamber and/or without depressurizing the ion implantation target chamber. Related methods and devices are also discussed.

Abstract: A semiconductor light emitting diode includes a semiconductor substrate, an epitaxial layer of n-type Group III nitride on the substrate, a p-type epitaxial layer of Group III nitride on the n-type epitaxial layer and forming a p-n junction with the n-type layer, and a resistive gallium nitride region on the n-type epitaxial layer and adjacent the p-type epitaxial layer for electrically isolating portions of the p-n junction. A metal contact layer is formed on the p-type epitaxial layer. In method embodiments disclosed, the resistive gallium nitride border is formed by forming an implant mask on the p-type epitaxial region and implanting ions into portions of the p-type epitaxial region to render portions of the p-type epitaxial region semi-insulating. A photoresist mask or a sufficiently thick metal layer may be used as the implant mask.

Abstract: A semiconductor light emitting diode includes a semiconductor substrate, an epitaxial layer of n-type Group III nitride on the substrate, a p-type epitaxial layer of Group III nitride on the n-type epitaxial layer and forming a p-n junction with the n-type layer, and a resistive gallium nitride region on the n-type epitaxial layer and adjacent the p-type epitaxial layer for electrically isolating portions of the p-n junction. A metal contact layer is formed on the p-type epitaxial layer. Some embodiments include a semiconductor substrate, an epitaxial layer of n-type Group III nitride on the substrate, a p-type epitaxial layer of Group III nitride on the n-type epitaxial layer and forming a p-n junction with the n-type layer, wherein portions of the epitaxial region are patterned into a mesa and wherein the sidewalls of the mesa comprise a resistive Group III nitride region for electrically isolating portions of the p-n junction.