Abstract: Semiconductor devices include a silicon carbide drift region having an upper portion and a lower portion. A first contact is on the upper portion of the drift region and a second contact is on the lower portion of the drift region. The drift region includes a superjunction structure that includes a p-n junction that is formed at an angle of between 10° and 30° from a plane that is normal to a top surface of the drift region. The p-n junction extends within +/?1.5° of a crystallographic axis of the silicon carbide material forming the drift region.

Abstract: Semiconductor devices include a silicon carbide drift region having an upper portion and a lower portion. A first contact is on the upper portion of the drift region and a second contact is on the lower portion of the drift region. The drift region includes a superjunction structure that includes a p-n junction that is formed at an angle of between 10° and 30° from a plane that is normal to a top surface of the drift region. The p-n junction extends within +/?1.5° of a crystallographic axis of the silicon carbide material forming the drift region.

Abstract: A power MOSFET includes a silicon carbide drift region having a first conductivity type, first and second well regions located in upper portions of the silicon carbide drift region that are doped with second conductivity dopants, and a channel region in a side portion of the first well region, an upper portion of the channel region having the first conductivity type, wherein a depth of the first well region is at least 1.5 microns and the depth of the first well region exceeds a distance between the first and second well regions.

Abstract: Semiconductor devices include a silicon carbide drift region having an upper portion and a lower portion. A first contact is on the upper portion of the drift region and a second contact is on the lower portion of the drift region. The drift region includes a superjunction structure that includes a p-n junction that is formed at an angle of between 10° and 30° from a plane that is normal to a top surface of the drift region. The p-n junction extends within +/?1.5° of a crystallographic axis of the silicon carbide material forming the drift region.

Abstract: A power MOSFET includes a silicon carbide drift region having a first conductivity type, first and second well regions located in upper portions of the silicon carbide drift region that are doped with second conductivity dopants, and a channel region in a side portion of the first well region, an upper portion of the channel region having the first conductivity type, wherein a depth of the first well region is at least 1.5 microns and the depth of the first well region exceeds a distance between the first and second well regions.

Abstract: A power MOSFET includes a silicon carbide drift region having a first conductivity type, first and second well regions located in upper portions of the silicon carbide drift region that are doped with second conductivity dopants, and a channel region in a side portion of the first well region, an upper portion of the channel region having the first conductivity type, wherein a depth of the first well region is at least 1.5 microns and the depth of the first well region exceeds a distance between the first and second well regions.

Abstract: A power MOSFET includes a silicon carbide drift region having a first conductivity type, first and second well regions located in upper portions of the silicon carbide drift region that are doped with second conductivity dopants, and a channel region in a side portion of the first well region, an upper portion of the channel region having the first conductivity type, wherein a depth of the first well region is at least 1.5 microns and the depth of the first well region exceeds a distance between the first and second well regions.

Abstract: Methods of forming a semiconductor structure include the use of channeled implants into silicon carbide crystals. Some methods include providing a silicon carbide layer having a crystallographic axis, heating the silicon carbide layer to a temperature of about 300° C. or more, implanting dopant ions into the heated silicon carbide layer at an implant angle between a direction of implantation and the crystallographic axis of less than about 2°, and annealing the silicon carbide layer at a time-temperature product of less than about 30,000° C.-hours to activate the implanted ions.

Abstract: A semiconductor device structure according to some embodiments includes a silicon carbide substrate having a first conductivity type, a silicon carbide drift layer having the first conductivity type on the silicon carbide substrate and having an upper surface opposite the silicon carbide substrate, and a buried junction structure in the silicon carbide drift layer. The buried junction structure has a second conductivity type opposite the first conductivity type and has a junction depth that is greater than about one micron.

Abstract: Methods of fabricating a semiconductor device include forming a first semiconductor layer of a first conductivity type and having a first dopant concentration, and forming a second semiconductor layer on the first semiconductor layer. The second semiconductor layer has a second dopant concentration that is less than the first dopant concentration. Ions are implanted into the second semiconductor layer to form an implanted region of the first conductivity type extending through the second semiconductor layer to contact the first semiconductor layer. A first electrode is formed on the implanted region of the second semiconductor layer, and a second electrode is formed on a non-implanted region of the second semiconductor layer. Related devices are also discussed.

Abstract: Methods of forming a semiconductor structure include the use of channeled implants into silicon carbide crystals. Some methods include providing a silicon carbide layer having a crystallographic axis, heating the silicon carbide layer to a temperature of about 300° C. or more, implanting dopant ions into the heated silicon carbide layer at an implant angle between a direction of implantation and the crystallographic axis of less than about 2°, and annealing the silicon carbide layer at a time-temperature product of less than about 30,000° C.-hours to activate the implanted ions.

Abstract: Semiconductor devices include a semiconductor layer structure having a wide band-gap semiconductor drift region having a first conductivity type. A gate trench is provided in an upper portion of the semiconductor layer structure, the gate trench having first and second opposed sidewalls that extend in a first direction in the upper portion of the semiconductor layer structure. These devices further include a deep shielding pattern having a second conductivity type that is opposite the first conductivity type in the semiconductor layer structure underneath a bottom surface of the gate trench, and a deep shielding connection pattern that has the second conductivity type in the first sidewall of the gate trench. The devices include a semiconductor channel region that has the first conductivity type in the second sidewall of the gate trench.

Abstract: Semiconductor devices include a silicon carbide drift region having an upper portion and a lower portion. A first contact is on the upper portion of the drift region and a second contact is on the lower portion of the drift region. The drift region includes a superjunction structure that includes a p-n junction that is formed at an angle of between 10° and 30° from a plane that is normal to a top surface of the drift region. The p-n junction extends within +/?1.5° of a crystallographic axis of the silicon carbide material forming the drift region.

Abstract: Methods of forming a semiconductor structure include the use of channeled implants into silicon carbide crystals. Some methods include providing a silicon carbide layer having a crystallographic axis, heating the silicon carbide layer to a temperature of about 300° C. or more, implanting dopant ions into the heated silicon carbide layer at an implant angle between a direction of implantation and the crystallographic axis of less than about 2°, and annealing the silicon carbide layer at a time-temperature product of less than about 30,000° C.-hours to activate the implanted ions.

Abstract: A semiconductor device structure according to some embodiments includes a silicon carbide substrate having a first conductivity type, a silicon carbide drift layer having the first conductivity type on the silicon carbide substrate and having an upper surface opposite the silicon carbide substrate, and a buried junction structure in the silicon carbide drift layer. The buried junction structure has a second conductivity type opposite the first conductivity type and has a junction depth that is greater than about one micron.

Abstract: A semiconductor device structure according to some embodiments includes a silicon carbide substrate having a first conductivity type, a silicon carbide drift layer having the first conductivity type on the silicon carbide substrate and having an upper surface opposite the silicon carbide substrate, and a buried junction structure in the silicon carbide drift layer. The buried junction structure has a second conductivity type opposite the first conductivity type and has a junction depth that is greater than about one micron.

Abstract: A semiconductor device structure according to some embodiments includes a silicon carbide substrate having a first conductivity type, a silicon carbide drift layer having the first conductivity type on the silicon carbide substrate and having an upper surface opposite the silicon carbide substrate, and a buried junction structure in the silicon carbide drift layer. The buried junction structure has a second conductivity type opposite the first conductivity type and has a junction depth that is greater than about one micron.

Abstract: Methods of forming a semiconductor structure include the use of channeled implants into silicon carbide crystals. Some methods include providing a silicon carbide layer having a crystallographic axis, heating the silicon carbide layer to a temperature of about 300° C. or more, implanting dopant ions into the heated silicon carbide layer at an implant angle between a direction of implantation and the crystallographic axis of less than about 2°, and annealing the silicon carbide layer at a time-temperature product of less than about 30,000° C.-hours to activate the implanted ions.

Abstract: Methods of fabricating a semiconductor device include forming a first semiconductor layer of a first conductivity type and having a first dopant concentration, and forming a second semiconductor layer on the first semiconductor layer. The second semiconductor layer has a second dopant concentration that is less than the first dopant concentration. Ions are implanted into the second semiconductor layer to form an implanted region of the first conductivity type extending through the second semiconductor layer to contact the first semiconductor layer. A first electrode is formed on the implanted region of the second semiconductor layer, and a second electrode is formed on a non-implanted region of the second semiconductor layer. Related devices are also discussed.

Abstract: Methods of fabricating a semiconductor device include forming a first semiconductor layer of a first conductivity type and having a first dopant concentration, and forming a second semiconductor layer on the first semiconductor layer. The second semiconductor layer has a second dopant concentration that is less than the first dopant concentration. Ions are implanted into the second semiconductor layer to form an implanted region of the first conductivity type extending through the second semiconductor layer to contact the first semiconductor layer. A first electrode is formed on the implanted region of the second semiconductor layer, and a second electrode is formed on a non-implanted region of the second semiconductor layer. Related devices are also discussed.