Abstract: Methods of forming oxide layers on silicon carbide layers are disclosed, including placing a silicon carbide layer in a chamber such as an oxidation furnace tube that is substantially free of metallic impurities, heating an atmosphere of the chamber to a temperature of about 500° C. to about 1300° C., introducing atomic oxygen in the chamber, and flowing the atomic oxygen over a surface of the silicon carbide layer to thereby form an oxide layer on the silicon carbide layer. In some embodiments, introducing atomic includes oxygen providing a source oxide in the chamber and flowing a mixture of nitrogen and oxygen gas over the source oxide. The source oxide may comprise aluminum oxide or another oxide such as manganese oxide. Some methods include forming an oxide layer on a silicon carbide layer and annealing the oxide layer in an atmosphere including atomic oxygen.

Abstract: Edge termination for silicon carbide devices has a plurality of concentric floating guard rings in a silicon carbide layer that are adjacent and spaced apart from a silicon carbide-based semiconductor junction. An insulating layer, such as an oxide, is provided on the floating guard rings and a silicon carbide surface charge compensation region is provided between the floating guard rings and is adjacent the insulating layer. Methods of fabricating such edge termination are also provided.

Abstract: Silicon carbide high voltage semiconductor devices and methods of fabricating such devices are provided. The devices include a voltage blocking substrate. Insulated gate bipolar transistors are provided that have a voltage blocking substrate. Planar and beveled edge termination may be provided.

Abstract: High voltage silicon carbide (SiC) devices, for example, thyristors, are provided. A first SiC layer having a first conductivity type is provided on a first surface of a voltage blocking SiC substrate having a second conductivity type. A first region of SiC is provided on the first SiC layer and has the second conductivity type. A second region of SiC is provided in the first SiC layer. The second region of SiC has the first conductivity type and is adjacent to the first region of SiC. A second SiC layer having the first conductivity type is provided on a second surface, opposite the first surface, of the voltage blocking SiC substrate. First, second and third contacts are provided on the first region of SiC, the second region of SiC and the second SiC layer, respectively. Related methods of fabricating high voltage SiC devices are also provided.

Abstract: An insulated gate bipolar transistor (IGBT) includes a substrate having a first conductivity type, a drift layer having a second conductivity type opposite the first conductivity type, and a well region in the drift layer and having the first conductivity type. An epitaxial channel adjustment layer is on the drift layer and has the second conductivity type. An emitter region extends from a surface of the epitaxial channel adjustment layer through the epitaxial channel adjustment layer and into the well region. The emitter region has the second conductivity type and at least partially defines a channel region in the well region adjacent to the emitter region. A gate oxide layer is on the channel region, and a gate is on the gate oxide layer. Related methods are also disclosed.

Abstract: A bipolar junction transistor (BJT) includes a silicon carbide (SiC) collector layer of first conductivity type, an epitaxial silicon carbide base layer of second conductivity type on the silicon carbide collector layer, and an epitaxial silicon carbide emitter mesa of the first conductivity type on the epitaxial silicon carbide base layer. An epitaxial silicon carbide passivation layer of the first conductivity type is provided on at least a portion of the epitaxial silicon carbide base layer outside the silicon carbide emitter mesa. The epitaxial silicon carbide passivation layer can be configured to fully deplete at zero device bias. Related fabrication methods also are disclosed.

Abstract: Bipolar junction transistors (BJTs) are provided including silicon carbide (SiC) substrates. An epitaxial SiC base region is provided on the SiC substrate. The epitaxial SiC base region has a first conductivity type. An epitaxial SiC emitter region is also provided on the SiC substrate. The epitaxial SiC emitter region has a second conductivity type, different from the first conductivity type. The epitaxial SiC emitter region has first and second portions. The first portion is provided on the SiC substrate and the second portion is provided on the first portion. The second portion has a higher carrier concentration than the first portion. Related methods of fabricating BJTs are also provided herein.

Abstract: Edge termination for silicon carbide devices has a plurality of concentric floating guard rings in a silicon carbide layer that are adjacent and spaced apart from a silicon carbide-based semiconductor junction. An insulating layer, such as an oxide, is provided on the floating guard rings and a silicon carbide surface charge compensation region is provided between the floating guard rings and is adjacent the insulating layer. Methods of fabricating such edge termination are also provided.

Abstract: Edge termination for silicon carbide devices has a plurality of concentric floating guard rings in a silicon carbide layer that are adjacent and spaced apart from a silicon carbide-based semiconductor junction. An insulating layer, such as an oxide, is provided on the floating guard rings and a silicon carbide surface charge compensation region is provided between the floating guard rings and is adjacent the insulating layer. Methods of fabricating such edge termination are also provided.

Abstract: Silicon carbide devices and methods of fabricating silicon carbide devices are provided by forming a first p-type silicon carbide epitaxial layer on an n-type silicon carbide substrate. At least one first region of n-type silicon carbide is formed extending through the first p-type silicon carbide epitaxial layer and to the n-type silicon carbide substrate so as to provide at least one channel region in the first p-type silicon carbide epitaxial layer. At least one second region of n-type silicon carbide is also formed adjacent and spaced apart from the first region of n-type silicon carbide. A gate dielectric is formed-over the first region of n-type silicon carbide and at least a portion of the second region of n-type silicon carbide. A gate contact is formed on the gate dielectric. A first contact is also formed so as to contact a portion of the p-type epitaxial layer and the second region of n-type silicon carbide. A second contact is also formed on the substrate.

Abstract: Silicon carbide devices and methods of fabricating silicon carbide devices are provided by forming a first p-type silicon carbide epitaxial layer on an n-type silicon carbide substrate. At least one first region of n-type silicon carbide is formed extending through the first p-type silicon carbide epitaxial layer and to the n-type silicon carbide substrate so as to provide at least one channel region in the first p-type silicon carbide epitaxial layer. At least one second region of n-type silicon carbide is also formed adjacent and spaced apart from the first region of n-type silicon carbide. A gate dielectric is formed-over the first region of n-type silicon carbide and at least a portion of the second region of n-type silicon carbide. A gate contact is formed on the gate dielectric. A first contact is also formed so as to contact a portion of the p-type epitaxial layer and the second region of n-type silicon carbide. A second contact is also formed on the substrate.

Abstract: Silicon carbide devices and methods of fabricating silicon carbide devices are provided by forming a first p-type silicon carbide epitaxial layer on an n-type silicon carbide substrate. At least one first region of n-type silicon carbide is formed extending through the first p-type silicon carbide epitaxial layer and to the n-type silicon carbide substrate so as to provide at least one channel region in the first p-type silicon carbide epitaxial layer. At least one second region of n-type silicon carbide is also formed adjacent and spaced apart from the first region of n-type silicon carbide. A gate dielectric is formed over the first region of n-type silicon carbide and at least a portion of the second region of n-type silicon carbide. A gate contact is formed on the gate dielectric. A first contact is also formed so as to contact a portion of the p-type epitaxial layer and the second region of n-type silicon carbide. A second contact is also formed on the substrate.

Abstract: A method of fabricating a self-aligned bipolar junction transistor in a semiconductor structure having a first layer of silicon carbide generally having a first conductivity type and a second layer of silicon carbide generally having a second conductivity type, opposite to the first conductivity type. The method comprises forming a pillar in the second silicon carbide layer, the pillar having a side wall and defining an adjacent horizontal surface on the second layer, forming a dielectric layer having a predetermined thickness on the second semiconductor layer, including the side wall and the horizontal surface. After formation of the dielectric layer, the dielectric layer on a portion of the horizontal surface adjacent the side wall is anisotropically etched while at least a portion of the dielectric layer remains on the side wall, thereby exposing a portion of the horizontal surface.

Abstract: A method of fabricating a self-aligned bipolar junction transistor in a semiconductor structure having a first layer of silicon carbide generally having a first conductivity type and a second layer of silicon carbide generally having a second conductivity type, opposite to the first conductivity type. The method comprises forming a pillar in the second silicon carbide layer, the pillar having a side wall and defining an adjacent horizontal surface on the second layer, forming a dielectric layer having a predetermined thickness on the second semiconductor layer, including the side wall and the horizontal surface. After formation of the dielectric layer, the dielectric layer on a portion of the horizontal surface adjacent the side wall is anisotropically etched while at least a portion of the dielectric layer remains on the side wall, thereby exposing a portion of the horizontal surface.

Abstract: A method of fabricating a self-aligned bipolar junction transistor in a semiconductor structure having a first layer of silicon carbide generally having a first conductivity type and a second layer of silicon carbide generally having a second conductivity type, opposite to the first conductivity type. The method comprises forming a pillar in the second silicon carbide layer, the pillar having a side wall and defining an adjacent horizontal surface on the second layer, forming a dielectric layer having a predetermined thickness on the second semiconductor layer, including the side wall and the horizontal surface. After formation of the dielectric layer, the dielectric layer on a portion of the horizontal surface adjacent the side wall is anisotropically etched while at least a portion of the dielectric layer remains on the side wall, thereby exposing a portion of the horizontal surface.

Abstract: A static induction transistor having source, drain and gate regions. Channel regions are defined between adjacent gates and a drift region is defined from the ends of the channel regions to the drain. The channel and drift regions have predetermined doping concentrations with the doping concentration of the channel regions being greater than the doping concentration of the drift region.

Abstract: A heat tolerant, frequency responsive transistor for use in the microwave region includes a collector region, a base region overlying the collector region, and an emitter region including an AlGaN layer overlying at least part of said base region, forming a heterojunction between said base region and said emitter region. The emitter region may include two layers. The HBT may be mounted on a SiC or sapphire substrate. The HBT may include a buffer layer between the substrate and the collector region.

Abstract: A static induction transistor having a silicon carbide substrate upon which is deposited a silicon carbide layer arrangement. The layer arrangement has a plurality of spaced gate regions for controlling current flow from a source region to a drain region vertically spaced from the source region by a drift layer. The pitch distance p between gate regions is 1 to 5 microns and the drift layer thickness d is also 1 to 5 microns.In one embodiment the source regions are positioned alternatively with the gate regions and are formed in a top layer of high doping concentration. In another embodiment the gate regions are ion implanted in the layer arrangement.In another embodiment the structure includes a dual oxide layer covering gate and source or drain regions, and in yet another embodiment contacts for the drain, source and gate regions are located on the same side of the substrate member.

Abstract: A static induction transistor includes a substrate and a drift layer with different doping levels. At least two mesas are formed on the drift layer and a heavily doped region is positioned on a top surface of each of the mesas. A gate contact extends along a bottom of a recess between the mesas and along a side of each of the mesas forming the recess. The gate contact also extends along a portion of the top surface of each of the mesas. In one embodiment of the invention, a notch is formed in the top surface of the mesas between the gate contact and the heavily doped region.

Abstract: A heat tolerant, frequency responsive transistor for use in the microwave region includes a collector region, a base region overlying the collector region, and an emitter region including an AlGaN layer overlying at least part of said base region, forming a heterojunction between said base region and said emitter region. The emitter region may include two layers. The HBT may be mounted on a SiC or sapphire substrate. The HBT may include a buffer layer between the substrate and the collector region.