A semiconductor thin film structure may include a substrate, a buffer layer on the substrate, and a semiconductor layer on the buffer layer, such that the buffer layer is between the semiconductor layer and the substrate. The buffer layer may include a plurality of unit layers. Each unit layer of the plurality of unit layers may include a first layer having first bandgap energy and a first thickness, a second layer having second bandgap energy and a second thickness, and a third layer having third bandgap energy and a third thickness. One layer having a lowest bandgap energy of the first, second, and third layers of the unit layer may be between another two layers of the first, second, and third layers of the unit layer.

A semiconductor thin film structure may include a substrate, a buffer layer on the substrate, and a semiconductor layer on the buffer layer, such that the buffer layer is between the semiconductor layer and the substrate. The buffer layer may include a plurality of unit layers. Each unit layer of the plurality of unit layers may include a first layer having first bandgap energy and a first thickness, a second layer having second bandgap energy and a second thickness, and a third layer having third bandgap energy and a third thickness. One layer having a lowest bandgap energy of the first, second, and third layers of the unit layer may be between another two layers of the first, second, and third layers of the unit layer.

A semiconductor body having a base carrier portion and a type III-nitride semiconductor portion is provided. The type III-nitride semiconductor portion includes a heterojunction and two-dimensional charge carrier gas. One or more ohmic contacts are formed in the type III-nitride semiconductor portion, the ohmic contacts forming an ohmic connection with the two-dimensional charge carrier gas. A gate structure is configured to control a conductive state of the two-dimensional charge carrier gas. Forming the one or more ohmic contacts comprises forming a structured laser-reflective mask on the upper surface of the type III-nitride semiconductor portion, implanting dopant atoms into the upper surface of the type III-nitride semiconductor portion, and performing a laser thermal anneal that activates the implanted dopant atoms.

A semiconductor body having a base carrier portion and a type III-nitride semiconductor portion is provided. The type III-nitride semiconductor portion includes a heterojunction and two-dimensional charge carrier gas. One or more ohmic contacts are formed in the type III-nitride semiconductor portion, the ohmic contacts forming an ohmic connection with the two-dimensional charge carrier gas. A gate structure is configured to control a conductive state of the two-dimensional charge carrier gas. Forming the one or more ohmic contacts comprises forming a structured laser-reflective mask on the upper surface of the type III-nitride semiconductor portion, implanting dopant atoms into the upper surface of the type III-nitride semiconductor portion, and performing a laser thermal anneal that activates the implanted dopant atoms.

An electronic component may include a carrier, and a thermoelectric sensor and a power transistor which are arranged on the carrier. The power transistor may include a base layer containing a transistor material chosen from among gallium nitride, aluminium gallium nitride, gallium arsenide, indium gallium, indium gallium nitride, aluminium nitride, indium aluminium nitride, and mixtures thereof. The electronic component may be configured so that the thermoelectric sensor generates an electric current under the effect of heating from the power transistor.

A method for manufacturing nitride semiconductor device includes a second step of forming, on a gate layer material film, a gate electrode film that is a material film of a gate electrode, a third step of selectively etching the gate electrode film to form the gate electrode 22 of a ridge shape, and a fourth step of selectively etching the gate layer material film to form a semiconductor gate layer 21 of a ridge shape with the gate electrode 22 disposed at a width intermediate portion of a front surface thereof. The third step includes a first etching step for forming a first portion 22A from an upper end to a thickness direction intermediate portion of the gate electrode 22 and a second etching step being a step differing in etching condition from the first etching step and being for forming a remaining second portion 22B of the gate electrode.

A method for manufacturing nitride semiconductor device includes a second step of forming, on a gate layer material film, a gate electrode film that is a material film of a gate electrode, a third step of selectively etching the gate electrode film to form the gate electrode 22 of a ridge shape, and a fourth step of selectively etching the gate layer material film to form a semiconductor gate layer 21 of a ridge shape with the gate electrode 22 disposed at a width intermediate portion of a front surface thereof. The third step includes a first etching step for forming a first portion 22A from an upper end to a thickness direction intermediate portion of the gate electrode 22 and a second etching step being a step differing in etching condition from the first etching step and being for forming a remaining second portion 22B of the gate electrode.

The structure and technology to improve the device performance of III-nitride semiconductor transistors at high drain voltage when the device is off is disclosed. P-type semiconductor regions are disposed between the gate electrode and the drain contact of the transistor structure. The P-type regions are electrically connected to the drain electrode. In some embodiments, the P-type regions are physically contacting the drain contact. In other embodiments, the P-type regions are physically separate from the drain contact, but electrically connected to the drain contact.

The structure and technology to improve the device performance of III-nitride semiconductor transistors at high drain voltage when the device is off is disclosed. P-type semiconductor regions are disposed between the gate electrode and the drain contact of the transistor structure. The P-type regions are electrically connected to the drain electrode. In some embodiments, the P-type regions are physically contacting the drain contact. In other embodiments, the P-type regions are physically separate from the drain contact, but electrically connected to the drain contact.

A device including a III-N material is described. The device includes a transistor structure having a first layer including a first group III-nitride (III-N) material, a polarization charge inducing layer above the first layer, the polarization charge inducing layer including a second III-N material, a gate electrode above the polarization charge inducing layer and a source structure and a drain structure on opposite sides of the gate electrode. The device further includes a plurality of peripheral structures adjacent to transistor structure, where each of the peripheral structure includes the first layer, but lacks the polarization charge inducing layer, an insulating layer above the peripheral structure and the transistor structure, wherein the insulating layer includes a first dielectric material. A metallization structure, above the peripheral structure, is coupled to the transistor structure.