A high electron mobility transistor includes: a first semiconductor layer over a substrate, and a second semiconductor layer over the first semiconductor layer, the second semiconductor layer having a band gap discontinuity with the first semiconductor layer, and at the first semiconductor layer and/or the second conductive layer includes indium. A top layer is over the second semiconductor layer, and a metal layer is over, and extends into, the top layer, the top layer separating the metal layer from the second semiconductor layer. A gate electrode is over the top layer, a third semiconductor layer being between the gate electrode and the top layer, where a sidewall of the third semiconductor layer and a sidewall of the metal layer are separated. A source and drain are on opposite sides of the gate electrode, the top layer extending continuously from below the source, below the gate electrode, and below the drain.

Structures for suppressing parasitic acoustic waves in semiconductor structures and integrated circuit devices are described. Such integrated circuit devices can, typically, produce undesirable acoustic wave resonances, and the acoustic waves can degrade the performance of the devices. In that context, some embodiments described herein relate to spoiling a conductive path that participates in the generation of acoustic waves. Some embodiments relate to spoiling acoustic characteristics of an acoustic resonant structure that may be present in the vicinity of the device. Combined embodiments that spoil the conductive path and acoustic characteristics are also possible.

A compound semiconductor substrate and a method for manufacturing the same are provided to suppress surface roughness of a barrier layer while suppressing gate leak.

A method for manufacturing of a compound semiconductor substrate comprises a step forming an electronic traveling layer consisting of a first nitride semiconductor, a step forming a barrier layer consisting of a second nitride semiconductor with a wider band gap than a band gap of the first nitride semiconductor on the electronic traveling layer, and a step forming a cap layer with an organometallic vapor phase epitaxy on the barrier layer and in contact with the barrier layer. The cap layer has a C concentration of 5*10.sup.17 atoms/cm.sup.3 or more and 1*10.sup.20 atoms/cm.sup.3 or less, and consists of a nitride semiconductor. During the step forming the cap layer, source gas of the nitride semiconductor forming the cap layer and hydrocarbon gas are introduced to a top surface of the barrier layer.

A method for fabricating a multi-layer resonator assembly includes sequentially fabricating a plurality of vertically-stacked resonator layers including, for each resonator layer of the plurality of resonator layers, depositing a dielectric layer, forming at least one film bulk acoustic resonator (FBAR) cavity in the deposited dielectric layer, filling each FBAR cavity of the at least one FBAR cavity with a sacrificial material block, and depositing a FBAR material stack over the at least one FBAR cavity. The deposited FBAR material stack is in contact with the sacrificial material block and the dielectric layer. The method further includes removing the sacrificial material block from the at least one FBAR cavity for each resonator layer of the plurality of resonator layers subsequent to sequentially fabricating the plurality of resonator layers.

A device includes a diode that includes a first group III-nitride (III-N) material and a transistor adjacent to the diode, where the transistor includes the first III-N material. The diode includes a second III-N material, a third III-N material between the first III-N material and the second III-N material, a first terminal including a metal in contact with the third III-N material, a second terminal coupled to the first terminal through the first group III-N material. The device further includes a transistor structure, adjacent to the diode structure. The transistor structure includes the first, second, and third III-N materials, a source and drain, a gate electrode and a gate dielectric between the gate electrode and each of the first, second and third III-N materials.

Embodiments are directed to high electron mobility transistor (HEMT) devices and methods. One such HEMT device includes a substrate having a first surface, and first and second heterostructures on the substrate and facing each other. Each of the first and second heterostructures includes a first semiconductor layer on the first surface of the substrate, a second semiconductor layer on the first surface of the substrate, and a two-dimensional electrode gas (2DEG) layer between the first and second semiconductor layers. A doped semiconductor layer is disposed between the first and second heterostructures, and a source contact is disposed on the first heterostructure and the second heterostructure.

Semiconductor devices includes third arms. A channel from the first and second arms extends to a channel of the third arm. When a current from a first voltage is flowing from the first arm to the second arm, a flow of ballistic electrons is generated that flow through the third arm channel from the channel of the first and second arms to the third arm channel. A fin structure located in the third arm channel and includes a gate. The gate is controlled using a second voltage over the fin structure, the fin structure is formed to induce an energy-field structure that shifts by an amount of the second voltage to control an opening of the gate that the flow of ballistic electrons pass through, which in turn changes a depletion width, subjecting the ballistic electrons to diffraction, and then interference.

A method for fabricating high electron mobility transistor (HEMT) includes the steps of: forming a buffer layer on a substrate; forming a patterned mask on the buffer layer; using the patterned mask to remove the buffer layer for forming ridges and a damaged layer on the ridges; removing the damaged layer; forming a barrier layer on the ridges; and forming a p-type semiconductor layer on the barrier layer.

A semiconductor device includes a first nitride-based semiconductor layer, a second nitride-based semiconductor layer, a group of negatively-charged ions, and a field plate. The gate electrode and the drain electrode disposed above the second nitride-based semiconductor layer to define a drift region therebetween. The group of negatively-charged ions are implanted into the drift region and spaced apart from an area directly beneath the gate and drain electrodes to form at least one high resistivity zone in the second nitride-based semiconductor layer. The field plate is disposed over the gate electrode and extends in a region between the gate electrode and the high resistivity zone.

A semiconductor device 1 has an electrode structure that includes source electrodes 3, a gate electrode 4, and drain electrodes 5 disposed on a semiconductor laminated structure 2 and extending in parallel to each other and in a predetermined first direction and a wiring structure that includes source wirings 9, drain wirings 10, and gate wirings 11 disposed on the electrode structure and extending in parallel to each other and in a second direction orthogonal to the first direction. The source wirings 9, the drain wirings 10, and the gate wirings 11 are electrically connected to the source electrodes 3, the drain electrodes 5, and the gate electrode 4, respectively. The semiconductor device 1 includes a conductive film 8 disposed between the gate electrode 4 and the drain wirings 10 and being electrically connected to the source electrodes 3.