Abstract: A method of fabricating a III-nitride power semiconductor device that includes growing a transition layer over a substrate using at least two distinct and different growth methods.

Abstract: A semiconductor package that includes a semiconductor die and a heat spreader thermally coupled to the semiconductor and disposed at least partially within the molded housing of the package.

Abstract: According to one disclosed embodiment, a method for fabricating a monolithic integrated composite device comprises forming a group III-V semiconductor body over a group IV semiconductor substrate, forming a trench in the group III-V semiconductor body, and forming a group IV semiconductor body in the trench. The method also comprises fabricating at least one group IV semiconductor device in the group IV semiconductor body, and fabricating at least one group III-V semiconductor device in the group III-V semiconductor body. In one embodiment, the method further comprises planarizing an upper surface of the III-V semiconductor body and an upper surface of the group IV semiconductor body to render those respective upper surfaces substantially co-planar. In one embodiment, the method further comprises fabricating at least one passive device in a defective region of said group IV semiconductor body adjacent to a sidewall of the trench.

Abstract: Disclosed is a III-nitride heterojunction device that includes a conduction channel having a two dimensional electron gas formed at an interface between a first III-nitride material and a second III-nitride material. A modification including a contact insulator, for example, a gate insulator formed under a gate contact, is disposed over the conduction channel, wherein the contact insulator includes aluminum to alter formation of the two dimensional electron gas at the interface. The contact insulator can include AlSiN, or can be SiN doped with aluminum. The modification results in programming the threshold voltage of the III-nitride heterojunction device to, for example, make the device an enhancement mode device. The modification can further include a recess, an ion implanted region, a diffused region, an oxidation region, and/or a nitridation region. In one embodiment, the first III-nitride material comprises GaN and the second III-nitride material comprises AlGaN.

Abstract: According to one embodiment, a III-nitride transistor includes a conduction channel formed between first and second III-nitride bodies, the conduction channel including a two-dimensional electron gas. The transistor also includes at least one gate dielectric layer having a charge confined within to cause an interrupted region of the conduction channel and a gate electrode operable to restore the interrupted region of the conduction channel. The transistor can be an enhancement mode transistor. In one embodiment, the gate dielectric layer is a silicon nitride layer. In another embodiment, the at least one gate dielectric layer is a silicon oxide layer. The charge can be ion implanted into the at least one gate dielectric layer. The at least one gate dielectric layer can also be grown with the charge.

Abstract: A power converter driver that is supplied with two different voltages.

Abstract: There are disclosed herein various implementations of composite semiconductor devices. In one implementation, such a composite semiconductor device includes a transition body formed over a diode, the transition body including more than one semiconductor layer. The composite semiconductor device also includes a transistor formed over the transition body. The diode may be connected across the transistor using through-semiconductor vias, external electrical connectors, or a combination of the two.

Abstract: According to one exemplary embodiment, a rectifier circuit includes a diode. A first depletion-mode transistor is connected to a cathode of the diode. Also, at least one second depletion-mode transistor is in parallel with the first depletion-mode transistor and is configured to supply a pre-determined current range to a cathode of the diode. A pinch off voltage of the at least one second depletion-mode transistor can be more negative than a pinch off voltage of the first depletion-mode transistor and the at least one second depletion-mode transistor can be configured to supply the pre-determined current range while the first depletion-mode transistor is OFF. Also, the pre-determined current range can be greater than a leakage current of the first depletion-mode transistor.

Abstract: According to an exemplary implementation, a transistor includes drain finger electrodes interdigitated with source finger electrodes. The transistor also includes a current conduction path in a semiconductor substrate between the drain finger electrodes and the source finger electrodes. At least one of the drain finger electrodes has a drain finger electrode end and a drain finger electrode main body, where the drain finger electrode main body is non-coplaner with at least a portion of the drain finger electrode end. The transistor may also include a dielectric material situated between at least a portion of the drain finger electrode end and the semiconductor substrate. The dielectric material can be an increasing thickness dielectric material. The dielectric material can thus elevate the drain finger electrode end over the semiconductor substrate. Further, the drain finger electrode end can have an increased radius of curvature.

Abstract: There are disclosed herein various implementations of a monolithically integrated high side block. Such a monolithically integrated high side block includes a level shifter, a high side driver coupled to the level shifter, and a high side power switch coupled to the high side driver. The high side power switch is monolithically integrated with the high side driver and the level shifter on a common die. Each of the level shifter, the high side driver, and the high side power switch includes at least one group III-V device.

Abstract: There are disclosed herein various implementations of a group III-V merged cascode transistor. Such a group III-V merged cascode transistor includes a group III-V body disposed over a substrate and configured to produce a two-dimensional electron gas (2DEG). The group III-V body includes a group III-V barrier layer situated over a group III-V channel layer, and a source electrode and a drain electrode. The group III-V merged cascode transistor also includes an enable gate disposed in a recess extending substantially through the group III-V barrier layer, and an operational gate disposed over the group III-V barrier layer, the operational gate not being in physical contact with the enable gate.

Abstract: There are disclosed herein various implementations of a normally off (enhancement mode) composite power device with an ESD protection clamp. Such a normally off composite power device includes a normally on (depletion mode) power transistor providing a composite drain of the normally off composite power device, and a normally off low voltage (LV) transistor cascoded with the normally on power transistor. The normally off LV transistor provides a composite source and a composite gate of the normally off composite power device. The normally off composite power device also includes the ESD protection clamp coupled between the composite source and the composite gate. The ESD protection clamp is configured to provide electrostatic discharge (ESD) protection for the normally off composite power device.

Abstract: There are disclosed herein various implementations of semiconductor structures including III-Nitride interlayer modules. One exemplary implementation comprises a substrate and a first transition body over the substrate. The first transition body has a first lattice parameter at a first surface and a second lattice parameter at a second surface opposite the first surface. The exemplary implementation further comprises a second transition body, such as a transition module, having a smaller lattice parameter at a lower surface overlying the second surface of the first transition body and a larger lattice parameter at an upper surface of the second transition body, as well as a III-Nitride semiconductor layer over the second transition body. The second transition body may consist of two or more transition modules, and each transition module may include two or more interlayers. The first and second transition bodies reduce strain for the semiconductor structure.

Abstract: There are disclosed herein various implementations of a group III-V transistor with a semiconductor field plate. Such a group III-V transistor includes a group III-V heterostructure situated over a substrate and configured to produce a two-dimensional electron gas (2DEG). In addition, the group III-V transistor includes a source electrode, a drain electrode, and a gate situated over the group heterostructure. The group III-V transistor also includes an insulator layer over the group III-V heterostructure and situated between the gate and the drain electrode, and a semiconductor field plate situated between the gate and the drain electrode, over the insulator layer.

Abstract: There are disclosed herein various implementations of an integrated half-bridge circuit with low side and high side composite switches. In one exemplary implementation, such an integrated half-bridge circuit includes a III-N body including first and second III-N field-effect transistors (FETs) monolithically integrated with and situated over a first group IV FET. The integrated half-bridge circuit also includes a second group IV FET stacked over the III-N body. The first group IV FET is cascoded with the first III-N FET to provide one of the low side and the high side composite switches, and the second group IV FET is cascoded with the second III-N FET to provide the other of the low side and the high side composite switches.

Abstract: There are disclosed herein various implementations of a III-Nitride device and method for its fabrication. The III-Nitride device includes a III-Nitride buffer layer situated over a substrate, the III-Nitride buffer layer having a first bandgap. In addition, the device includes a III-Nitride heterostructure situated over the III-Nitride buffer layer and configured to produce a two-dimensional electron gas (2DEG); the III-Nitride heterostructure including a channel layer having a second bandgap smaller than the first bandgap. The III-Nitride device also includes a buffer termination body situated between the III-Nitride buffer layer and the channel layer, the buffer termination body including a III-Nitride material having a third bandgap smaller than the first bandgap and larger the second bandgap.

Abstract: A power converter driver that is supplied with two different voltages.

Abstract: In one implementation, a stacked composite device comprises a group IV lateral transistor and a group III-V transistor stacked over the group IV lateral transistor. A drain of the group IV lateral transistor is in contact with a source of the group III-V transistor, a source of the group IV lateral transistor is coupled to a gate of the group III-V transistor to provide a composite source on a top side of the stacked composite device, and a drain of the group III-V transistor provides a composite drain on the top side of the stacked composite device. A gate of the group IV lateral transistor provides a composite gate on the top side of the stacked composite device, and a substrate of the group IV lateral transistor is on a bottom side of the stacked composite device.

Abstract: There are disclosed herein various implementations of nested composite switches. In one implementation, a nested composite switch includes a normally ON primary transistor coupled to a composite switch. The composite switch includes a low voltage (LV) transistor cascoded with an intermediate transistor having a breakdown voltage greater than the LV transistor and less than the normally ON primary transistor. In one implementation, the normally on primary transistor may be a group III-V transistor and the LV transistor may be an LV group IV transistor.

Abstract: In an exemplary implementation, a III-nitride semiconductor device includes a III-nitride heterojunction including a first III-nitride body situated over a second III-nitride body to form a two-dimensional electron gas. The III-nitride semiconductor device further includes a dielectric body situated over the III-nitride heterojunction and including a first dielectric layer of a first dielectric material and a second dielectric layer of a second dielectric material different than the first dielectric material. A gate well of a first width is defined by the first dielectric layer, and is of a second width defined by the second dielectric layer, where the second width is greater than the first width. The III-nitride semiconductor device further includes a gate arrangement situated in the gate well and including a gate electrode integrated with a field plate.