Abstract: In one example, an apparatus comprises: a voltage sensing circuit having a voltage sensing terminal and a voltage sensing output, the voltage sensing circuit configured to generate a first voltage at the voltage sensing output representing a second voltage at the voltage sensing terminal; a control circuit having a control circuit input and a control circuit output, the control circuit input coupled to the voltage sensing output, the control circuit configured to: determine a state of a transistor based on the first voltage; and generate a driver signal at the control circuit output based on the state; and a driver circuit having a driver input and a switch control output, the driver input coupled to the control circuit output, the driver circuit configured to provide a current at the switch control output responsive to the driver signal.

Abstract: In one example, an apparatus comprises: a voltage sensing circuit having a voltage sensing terminal and a voltage sensing output, the voltage sensing circuit configured to generate a first voltage at the voltage sensing output representing a second voltage at the voltage sensing terminal; a control circuit having a control circuit input and a control circuit output, the control circuit input coupled to the voltage sensing output, the control circuit configured to: determine a state of a transistor based on the first voltage; and generate a driver signal at the control circuit output based on the state; and a driver circuit having a driver input and a switch control output, the driver input coupled to the control circuit output, the driver circuit configured to provide a current at the switch control output responsive to the driver signal.

Abstract: In one example, an apparatus comprises: a voltage sensing circuit having a voltage sensing terminal and a voltage sensing output, the voltage sensing circuit configured to generate a first voltage at the voltage sensing output representing a second voltage at the voltage sensing terminal; a control circuit having a control circuit input and a control circuit output, the control circuit input coupled to the voltage sensing output, the control circuit configured to: determine a state of a transistor based on the first voltage; and generate a driver signal at the control circuit output based on the state; and a driver circuit having a driver input and a switch control output, the driver input coupled to the control circuit output, the driver circuit configured to provide a current at the switch control output responsive to the driver signal.

Abstract: A semiconductor device includes a body, a gate oxide layer, and a gate electrode. The body is defined by a drift region and one or more implant regions. A junction field effect region is defined between one of the implant regions and another one of the implant regions. The gate oxide layer is grown as a single, unitary structure extending across the semiconductor body and at least partially overlap the implant regions. The gate oxide layer is additionally defined by a central expansion region between the implant regions, and extend into the junction field effect region. A gate electrode is disposed on the gate oxide layer.

Abstract: A device receives and stores location data and cargo transportation data. The cargo transportation data is received from a first system of a carrier and one or more other systems of partner carriers. The device receives, from the first system, a transportation availability request that is to be used to schedule transportation of cargo. The device generates and provides the first system with a recommendation that specifies recommended routes that may be used to assist in transporting the cargo. The device receives, from the first system, a booking request that identifies a selected route that vehicles are to use to transport the cargo, and provides the booking request to one or more other systems. The device receives a booking response from a second system of a partner carrier and provides the first system with an indication of whether the partner carrier has provided confirmation of assistance in transporting the cargo.

Abstract: A device receives and stores location data and cargo transportation data. The cargo transportation data is received from a first system of a carrier and one or more other systems of partner carriers. The device receives, from the first system, a transportation availability request that is to be used to schedule transportation of cargo. The device generates and provides the first system with a recommendation that specifies recommended routes that may be used to assist in transporting the cargo. The device receives, from the first system, a booking request that identifies a selected route that vehicles are to use to transport the cargo, and provides the booking request to one or more other systems. The device receives a booking response from a second system of a partner carrier and provides the first system with an indication of whether the partner carrier has provided confirmation of assistance in transporting the cargo.

Abstract: An electronic device includes a drift region having a first conductivity type and a grid including a plurality of doped regions formed in the drift region and having a second conductivity type. The doped regions have a dopant concentration greater than 2.2×1019 cm?3. Related methods are also disclosed.

Abstract: Methods of forming a p-channel MOS device in silicon carbide include forming an n-type well in a silicon carbide layer, and implanting p-type dopant ions to form a p-type region in the n-type well at a surface of the silicon carbide layer and at least partially defining a channel region in the n-type well adjacent the p-type region. A threshold adjustment region is formed in the channel region. The implanted ions are annealed in an inert atmosphere at a temperature greater than 1650° C. A gate oxide layer is formed on the channel region, and a gate is formed on the gate oxide layer. A silicon carbide-based transistor includes a silicon carbide layer, an n-type well in the silicon carbide layer, and a p-type region in the n-type well at a surface of the silicon carbide layer and at least partially defining a channel region in the n-type well adjacent the p-type region.

Abstract: A silicon carbide power device is fabricated by forming a p-type silicon carbide epitaxial layer on an n-type silicon carbide substrate, and forming a silicon carbide power device structure on the p-type silicon carbide epitaxial layer. The n-type silicon carbide substrate is at least partially removed, so as to expose the p-type silicon carbide epitaxial layer. An ohmic contact is formed on at least some of the p-type silicon carbide epitaxial layer that is exposed. By at least partially removing the n-type silicon carbide substrate and forming an ohmic contact on the p-type silicon carbide epitaxial layer, the disadvantages of using a p-type substrate may be reduced or eliminated. Related structures are also described.

Abstract: Methods of forming a p-channel MOS device in silicon carbide include forming an n-type well in a silicon carbide layer, and implanting p-type dopant ions to form a p-type region in the n-type well at a surface of the silicon carbide layer and at least partially defining a channel region in the n-type well adjacent the p-type region. A threshold adjustment region is formed in the channel region. The implanted ions are annealed in an inert atmosphere at a temperature greater than 1650° C. A gate oxide layer is formed on the channel region, and a gate is formed on the gate oxide layer. A silicon carbide-based transistor includes a silicon carbide layer, an n-type well in the silicon carbide layer, and a p-type region in the n-type well at a surface of the silicon carbide layer and at least partially defining a channel region in the n-type well adjacent the p-type region.

Abstract: Methods of forming a p-channel MOS device in silicon carbide include forming an n-type well in a silicon carbide layer, and implanting p-type dopant ions to form a p-type region in the n-type well at a surface of the silicon carbide layer and at least partially defining a channel region in the n-type well adjacent the p-type region. A threshold adjustment region is formed in the channel region. The implanted ions are annealed in an inert atmosphere at a temperature greater than 1650° C. A gate oxide layer is formed on the channel region, and a gate is formed on the gate oxide layer. A silicon carbide-based transistor includes a silicon carbide layer, an n-type well in the silicon carbide layer, and a p-type region in the n-type well at a surface of the silicon carbide layer and at least partially defining a channel region in the n-type well adjacent the p-type region.

Abstract: MOS channel devices and methods of fabricating such devices having a hybrid channel are provided. Exemplary devices include vertical power MOSFETs that include a hybrid well region of silicon carbide and methods of fabricating such devices are provided. The hybrid well region may include an implanted p-type silicon carbide well portion in a p-type silicon carbide epitaxial layer, an implanted p-type silicon carbide contact portion that contacts the implanted p-type silicon carbide well portion and extends to a surface of the p-type epitaxial layer and/or an epitaxial p-type silicon carbide portion, at least a portion of the epitaxial p-type silicon carbide well portion corresponding to a p-type channel region of the MOSFET.

Abstract: A silicon carbide power device is fabricated by forming a p-type silicon carbide epitaxial layer on an n-type silicon carbide substrate, and forming a silicon carbide power device structure on the p-type silicon carbide epitaxial layer. The n-type silicon carbide substrate is at least partially removed, so as to expose the p-type silicon carbide epitaxial layer. An ohmic contact is formed on at least some of the p-type silicon carbide epitaxial layer that is exposed. By at least partially removing the n-type silicon carbide substrate and forming an ohmic contact on the p-type silicon carbide epitaxial layer, the disadvantages of using a p-type substrate may be reduced or eliminated. Related structures are also described.

Abstract: Methods of forming a p-channel MOS device in silicon carbide include forming an n-type well in a silicon carbide layer, and implanting p-type dopant ions to form a p-type region in the n-type well at a surface of the silicon carbide layer and at least partially defining a channel region in the n-type well adjacent the p-type region. A threshold adjustment region is formed in the channel region. The implanted ions are annealed in an inert atmosphere at a temperature greater than 1650° C. A gate oxide layer is formed on the channel region, and a gate is formed on the gate oxide layer. A silicon carbide-based transistor includes a silicon carbide layer, an n-type well in the silicon carbide layer, and a p-type region in the n-type well at a surface of the silicon carbide layer and at least partially defining a channel region in the n-type well adjacent the p-type region.

Abstract: MOS channel devices and methods of fabricating such devices having a hybrid channel are provided. Exemplary devices include vertical power MOSFETs that include a hybrid well region of silicon carbide and methods of fabricating such devices are provided. The hybrid well region may include an implanted p-type silicon carbide well portion in a p-type silicon carbide epitaxial layer, an implanted p-type silicon carbide contact portion that contacts the implanted p-type silicon carbide well portion and extends to a surface of the p-type epitaxial layer and/or an epitaxial p-type silicon carbide portion, at least a portion of the epitaxial p-type silicon carbide well portion corresponding to a p-type channel region of the MOSFET.

Abstract: Silicon carbide structures are fabricated by fabricating a nitrided oxide layer on a layer of silicon carbide and annealing the nitrided oxide layer in an environment containing hydrogen. Such a fabrication of the nitrided oxide layer may be provided by forming the oxide layer in at least one of nitric oxide and nitrous oxide and/or annealing an oxide layer in at least one of nitric oxide and nitrous oxide. Alternatively, the nitrided oxide layer may be provided by fabricating an oxide layer and fabricating a nitride layer on the oxide layer so as to provide the nitrided oxide layer on which the nitride layer is fabricated. Furthermore, annealing the oxide layer may be provided as a separate step and/or substantially concurrently with another step such as fabricating the nitride layer or performing a contact anneal. The hydrogen environment may be pure hydrogen, hydrogen combined with other gases and/or result from a hydrogen precursor. Anneal temperatures of 400° C. or greater are preferred.

Abstract: A nitrided oxide layer on a silicon carbide layer is processed by annealing the nitrided oxide layer in a substantially oxygen-free nitrogen containing ambient. The anneal may be carried out at a temperature of greater than about 900° C., for example, a temperature of about 1100° C., a temperature of about 1200° C. or a temperature of about 1300° C. Annealing the nitrided oxide layer may be carried out at a pressure of less than about 1 atmosphere, for example, at a pressure of from about 0.01 to about 1 atm or, in particular, at a pressure of about 0.2 atm. The nitrided oxide layer may be an oxide layer that is grown in a N2O and/or NO containing ambient, that is annealed in a N2O and/or NO containing ambient or that is grown and annealed in a N2O and/or NO containing ambient.

Abstract: Capacitors and interconnection structures for silicon carbide are provided having an oxide layer, a layer of dielectric material and a second oxide layer on the layer of dielectric material. The thickness of the oxide layers may be from about 0.5 to about 33 percent of the thickness of the oxide layers and the layer of dielectric material. Capacitors and interconnection structures for silicon carbide having silicon oxynitride layer as a dielectric structure are also provided. Such a dielectric structure may be between metal layers to provide a metal-insulator-metal capacitor or may be used as a inter-metal dielectric of an interconnect structure so as to provide devices and structures having improved mean time to failure. Methods of fabricating such capacitors and structures are also provided.

Abstract: Capacitors and interconnection structures for silicon carbide are provided having an oxide layer, a layer of dielectric material and a second oxide layer on the layer of dielectric material. The thickness of the oxide layers may be from about 0.5 to about 33 percent of the thickness of the oxide layers and the layer of dielectric material. Capacitors and interconnection structures for silicon carbide having silicon oxynitride layer as a dielectric structure are also provided. Such a dielectric structure may be between metal layers to provide a metal-insulator-metal capacitor or may be used as a inter-metal dielectric of an interconnect structure so as to provide devices and structures having improved mean time to failure. Methods of fabricating such capacitors and structures are also provided.

Abstract: Silicon carbide metal-oxide semiconductor field effect transistors (MOSFETs) and methods of fabricating silicon carbide MOSFETs are provided. The silicon carbide MOSFETs have an n-type silicon carbide drift layer, spaced apart p-type silicon carbide regions in the n-type silicon carbide drift layer and having n-type silicon carbide regions therein, and a nitrided oxide layer. The MOSFETs also have n-type shorting channels extending from respective ones of the n-type silicon carbide regions through the p-type silicon carbide regions to the n-type silicon carbide drift layer. In further embodiments, silicon carbide MOSFETs and methods of fabricating silicon carbide MOSFETs are provided that include a region that is configured to self-deplete the source region, between the n-type silicon carbide regions and the drift layer, adjacent the oxide layer, upon application of a zero gate bias.