Abstract: Transistors are fabricated by forming a nitride-based semiconductor barrier layer on a nitride-based semiconductor channel layer and forming a protective layer on a gate region of the nitride-based semiconductor barrier layer. Patterned ohmic contact metal regions are formed on the barrier layer and annealed to provide first and second ohmic contacts. The annealing is carried out with the protective layer on the gate region. A gate contact is also formed on the gate region of the barrier layer. Transistors having protective layer in the gate region are also provided as are transistors having a barrier layer with a sheet resistance substantially the same as an as-grown sheet resistance of the barrier layer.

Abstract: An anneal of a gate recess prior to formation of a gate contact, such as a Schottky contact, may reduce gate leakage and/or provide a high quality gate contact in a semiconductor device, such as a transistor. The use of an encapsulation layer during the anneal may further reduce damage to the semiconductor in the gate recess of the transistor. The anneal may be provided, for example, by an anneal of ohmic contacts of the device. Thus, high quality gate and ohmic contacts may be provided with reduced degradation of the gate region that may result from providing a recessed gate structure as a result of etch damage in forming the recess.

Abstract: Semiconductor device structures and methods of fabricating semiconductor devices structures are provided that include a semi-insulating or insulating GaN epitaxial layer on a conductive semiconductor substrate and/or a conductive layer. The semi-insulating or insulating GaN epitaxial layer has a thickness of at least about 4 ?m. GaN semiconductor device structures and methods of fabricating GaN semiconductor device structures are also provided that include an electrically conductive SiC substrate and an insulating or semi-insulating GaN epitaxial layer on the conductive SiC substrate. The GaN epitaxial layer has a thickness of at least about 4 ?m.

Abstract: High electron mobility transistors are provided that include a non-uniform aluminum concentration AlGaN based cap layer having a high aluminum concentration adjacent a surface of the cap layer that is remote from the barrier layer on which the cap layer is provided. High electron mobility transistors are provided that include a cap layer having a doped region adjacent a surface of the cap layer that is remote from the barrier layer on which the cap layer is provided. Graphitic BN passivation structures for wide bandgap semiconductor devices are provided. SiC passivation structures for Group III-nitride semiconductor devices are provided. Oxygen anneals of passivation structures are also provided. Ohmic contacts without a recess are also provided.

Abstract: High electron mobility transistors and/or methods of fabricating high electron mobility transistors that include a first Group III-nitride layer having vertically grown regions, laterally grown regions and a coalescence region are provided. A Group III-nitride channel layer is provided on the first Group III-nitride layer and a Group III-nitride barrier layer is provided on the Group III-nitride channel layer. A drain contact, a source contact and a gate contact are provided on the barrier layer. The gate contact is disposed on a portion of the barrier layer on a laterally grown region of the first Group III-nitride layer and at least a portion of one of the source contact and/or the drain contact is disposed on a portion of the barrier layer on a vertically grown region of the first Group III-nitride layer.

Abstract: Group III Nitride based field effect transistor (FETs) are provided having a power degradation of less than about 3.0 dB when operated at a drain-to-source voltage (VDS) of about from about 28 to about 70 volts, a gate to source voltage (Vgs) of from about ?3.3 to about ?14 volts and a normal operating temperature for at least about 10 hours.

Abstract: Semiconductor device structures and methods of fabricating semiconductor devices structures are provided that include a semi-insulating or insulating GaN epitaxial layer on a conductive semiconductor substrate and/or a conductive layer. The semi-insulating or insulating GaN epitaxial layer has a thickness of at least about 4 ?m. GaN semiconductor device structures and methods of fabricating GaN semiconductor device structures are also provided that include an electrically conductive SiC substrate and an insulating or semi-insulating GaN epitaxial layer on the conductive SiC substrate. The GaN epitaxial layer has a thickness of at least about 4 ?m.

Abstract: Semiconductor device structures and methods of fabricating semiconductor devices structures are provided that include a semi-insulating or insulating GaN epitaxial layer on a conductive semiconductor substrate and/or a conductive layer. The semi-insulating or insulating GaN epitaxial layer has a thickness of at least about 4 ?m. GaN semiconductor device structures and methods of fabricating GaN semiconductor device structures are also provided that include an electrically conductive SiC substrate and an insulating or semi-insulating GaN epitaxial layer on the conductive SiC substrate. The GaN epitaxial layer has a thickness of at least about 4 ?m.

Abstract: Group III Nitride based field effect transistor (FETs) are provided having a power degradation of less than about 3.0 dB when operated at a drain-to-source voltage (VDS) of about from about 28 to about 70 volts, a gate to source voltage (Vgs) of from about ?3.3 to about ?14 volts and a normal operating temperature for at least about 10 hours.

Abstract: Group III Nitride based field effect transistor (FETs) are provided having a power degradation of less than about 3.0 dB when operated at a drain-to-source voltage (VDS) of about from about 28 to about 70 volts, a gate to source voltage (Vgs) of from about ?3.3 to about ?14 volts and a normal operating temperature for at least about 10 hours.

Abstract: Transistors are fabricated by forming a protective layer having a first opening extending therethrough on a substrate, forming a dielectric layer on the protective layer having a second opening extending therethrough that is wider than the first opening, and forming a gate electrode in the first and second openings. A first portion of the gate electrode laterally extends on surface portions of the protective layer outside the first opening, and a second portion of the gate electrode is spaced apart from the protective layer and laterally extends beyond the first portion on portions of the dielectric layer outside the second opening. Related devices and fabrication methods are also discussed.

Abstract: Transistors are fabricated by forming a nitride-based semiconductor barrier layer on a nitride-based semiconductor channel layer and forming a protective layer on a gate region of the nitride-based semiconductor barrier layer. Patterned ohmic contact metal regions are formed on the barrier layer and annealed to provide first and second ohmic contacts. The annealing is carried out with the protective layer on the gate region. A gate contact is also formed on the gate region of the barrier layer. Transistors having protective layer in the gate region are also provided as are transistors having a barrier layer with a sheet resistance substantially the same as an as-grown sheet resistance of the barrier layer.

Abstract: Transistors are fabricated by forming a nitride-based semiconductor barrier layer on a nitride-based semiconductor channel layer and forming a protective layer on a gate region of the nitride-based semiconductor barrier layer. Patterned ohmic contact metal regions are formed on the barrier layer and annealed to provide first and second ohmic contacts. The annealing is carried out with the protective layer on the gate region. A gate contact is also formed on the gate region of the barrier layer. Transistors having protective layer in the gate region are also provided as are transistors having a barrier layer with a sheet resistance substantially the same as an as-grown sheet resistance of the barrier layer.

Abstract: A passivated semiconductor structure and associated method are disclosed. The structure includes a silicon carbide substrate or layer; an oxidation layer on the silicon carbide substrate for lowering the interface density between the silicon carbide substrate and the thermal oxidation layer; a first sputtered non-stoichiometric silicon nitride layer on the thermal oxidation layer for reducing parasitic capacitance and minimizing device trapping; a second sputtered non-stoichiometric silicon nitride layer on the first layer for positioning subsequent passivation layers further from the substrate without encapsulating the structure; a sputtered stoichiometric silicon nitride layer on the second sputtered layer for encapsulating the structure and for enhancing the hydrogen barrier properties of the passivation layers; and a chemical vapor deposited environmental barrier layer of stoichiometric silicon nitride for step coverage and crack prevention on the encapsulant layer.

Abstract: Transistors are fabricated by forming a protective layer having a first opening extending therethrough on a substrate, forming a dielectric layer on the protective layer having a second opening extending therethrough that is wider than the first opening, and forming a gate electrode in the first and second openings. A first portion of the gate electrode laterally extends on surface portions of the protective layer outside the first opening, and a second portion of the gate electrode is spaced apart from the protective layer and laterally extends beyond the first portion on portions of the dielectric layer outside the second opening. Related devices and fabrication methods are also discussed.

Abstract: An anneal of a gate recess prior to formation of a gate contact, such as a Schottky contact, may reduce gate leakage and/or provide a high quality gate contact in a semiconductor device, such as a transistor. The use of an encapsulation layer during the anneal may further reduce damage to the semiconductor in the gate recess of the transistor. The anneal may be provided, for example, by an anneal of ohmic contacts of the device. Thus, high quality gate and ohmic contacts may be provided with reduced degradation of the gate region that may result from providing a recessed gate structure as a result of etch damage in forming the recess.

Abstract: Transistors are fabricated by forming a protective layer having a first opening extending therethrough on a substrate, forming a dielectric layer on the protective layer having a second opening extending therethrough that is wider than the first opening, and forming a gate electrode in the first and second openings. A first portion of the gate electrode laterally extends on surface portions of the protective layer outside the first opening, and a second portion of the gate electrode is spaced apart from the protective layer and laterally extends beyond the first portion on portions of the dielectric layer outside the second opening. Related devices and fabrication methods are also discussed.

Abstract: High electron mobility transistors are provided that include a non-uniform aluminum concentration AlGaN based cap layer having a high aluminum concentration adjacent a surface of the cap layer that is remote from the barrier layer on which the cap layer is provided. High electron mobility transistors are provided that include a cap layer having a doped region adjacent a surface of the cap layer that is remote from the barrier layer on which the cap layer is provided. Graphitic BN passivation structures for wide bandgap semiconductor devices are provided. SiC passivation structures for Group III-nitride semiconductor devices are provided. Oxygen anneals of passivation structures are also provided. Ohmic contacts without a recess are also provided.

Abstract: An anneal of a gate recess prior to formation of a gate contact, such as a Schottky contact, may reduce gate leakage and/or provide a high quality gate contact in a semiconductor device, such as a transistor. The use of an encapsulation layer during the anneal may further reduce damage to the semiconductor in the gate recess of the transistor. The anneal may be provided, for example, by an anneal of ohmic contacts of the device. Thus, high quality gate and ohmic contacts may be provided with reduced degradation of the gate region that may result from providing a recessed gate structure as a result of etch damage in forming the recess.

Abstract: High electron mobility transistors and/or methods of fabricating high electron mobility transistors that include a first Group III-nitride layer having vertically grown regions, laterally grown regions and a coalescence region are provided. A Group III-nitride channel layer is provided on the first Group III-nitride layer and a Group III-nitride barrier layer is provided on the Group III-nitride channel layer. A drain contact, a source contact and a gate contact are provided on the barrier layer. The gate contact is disposed on a portion of the barrier layer on a laterally grown region of the first Group III-nitride layer and at least a portion of one of the source contact and/or the drain contact is disposed on a portion of the barrier layer on a vertically grown region of the first Group III-nitride layer.