Embodiments of the invention provide methods for forming III-V gate-all-around field effect transistors on silicon substrates that utilize Aspect-Ratio Trapping to reduce or eliminate dislocation defects associated with lattice mismatches. A field dielectric material defining a trench is formed on a crystalline silicon substrate. A channel feature comprising III-V material is subsequently formed inside the trench. Source/drain features are then formed at both ends of the channel feature inside the trench. Lastly, gate dielectric layers and a gate feature are formed surrounding a portion of the channel feature.

Example embodiments relate to a metal-oxide semiconductor field effect transistor (MOSFET) of a high performance operating with a necessary threshold voltage while including a channel region formed based on a group III-V compound, and a method of manufacturing the MOSFET. The MOSFET includes a substrate, a semiconductor layer including a group III-V compound on the substrate, and a gate structure disposed on the semiconductor layer, and including a gate electrode formed based on metal and undergone an ion implantation process.

A compound semiconductor device includes: a first layer of nitride semiconductor, the first layer being doped with Fe; a channel layer of nitride semiconductor above the first layer; and a barrier layer of nitride semiconductor above the channel layer, wherein the channel layer includes: a two-dimensional electron gas region in which the two-dimensional electron gas exists; and an Al-containing region between the two-dimensional electron gas region and the first layer, an Al concentration in the Al-containing region being 510.sup.17 atoms/cm.sup.3 or more and less than 110.sup.19 atoms/cm.sup.3.

Embodiments are directed to glass-ceramic substrates with a III-V semiconductor layer, for example, a GaN layer that can be used in LED lighting devices. The glass-ceramics material is in the anorthite-rutile (CaAl.sub.2Si.sub.2O.sub.8+TiO.sub.2) family or in the cordierite-enstatite (SiO.sub.2Al.sub.2O.sub.3MgOTiO.sub.2) family.

Vertical field effect transistor (FET) device with tunable bandgap source/drain regions are provided, as well as methods for fabricating such vertical FET devices. For example, a vertical FET device includes a lower source/drain region formed on a substrate, a vertical semiconductor fin formed on the lower source/drain region, and an upper source/drain region formed on an upper region of the vertical semiconductor fin. The lower source/drain region and vertical semiconductor fin are formed of a first type of III-V semiconductor material. The upper source/drain region is formed of a second type of III-V semiconductor material which comprises the first type of III-V semiconductor material and at least one additional element that increases a bandgap of the second type of III-V semiconductor material of the upper source/drain region relative to a bandgap of the first type of III-V compound semiconductor material of the lower source/drain region and the vertical semiconductor fin.

An alternating stack of layers of a first epitaxial semiconductor material and a second epitaxial semiconductor material is formed on a substrate. A fin stack is formed by patterning the alternating stack into a shape of a fin having a parallel pair of vertical sidewalls. After formation of a disposable gate structure and an optional gate spacer, raised active regions can be formed on end portions of the fin stack. A planarization dielectric layer is formed, and the disposable gate structure is subsequently removed to form a gate cavity. A crystallographic etch is performed on the first epitaxial semiconductor material to form vertically separated pairs of an upright triangular semiconductor nanowire and an inverted triangular semiconductor nanowire. Portions of the epitaxial disposable material are subsequently removed. After an optional anneal, the gate cavity is filled with a gate dielectric and a gate electrode to form a field effect transistor.

A field effect transistor is provided. The field effect transistor may include a capping layer on a substrate, a source ohmic electrode and a drain ohmic electrode on the capping layer, a first insulating layer and a second insulating layer stacked on the capping layer to cover the source and drain ohmic electrodes, a -shaped gate electrode including a leg portion and a head portion, the leg portion being connected to the substrate between the source ohmic electrode and the drain ohmic electrode, and the head portion extending from the leg portion to cover a top surface of the second insulating layer, a first planarization layer on the second insulating layer to cover the -shaped gate electrode, and a first electrode on the first planarization layer, the first electrode being connected to the source ohmic electrode or the drain ohmic electrode.

A solution for designing and/or fabricating a structure including a quantum well and an adjacent barrier is provided. A target band discontinuity between the quantum well and the adjacent barrier is selected to coincide with an activation energy of a dopant for the quantum well and/or barrier. For example, a target valence band discontinuity can be selected such that a dopant energy level of a dopant in the adjacent barrier coincides with a valence energy band edge for the quantum well and/or a ground state energy for free carriers in a valence energy band for the quantum well. Additionally, a target doping level for the quantum well and/or adjacent barrier can be selected to facilitate a real space transfer of holes across the barrier. The quantum well and the adjacent barrier can be formed such that the actual band discontinuity and/or actual doping level(s) correspond to the relevant target(s).

A semiconductor device includes a semiconductor substrate and a p-doped layer formed on the substrate having a dislocation density exceeding 10 cm.sup.2. An n-type layer is formed on or in the p-doped layer. The n-type layer includes a II-VI material configured to tolerate the dislocation density to form an electronic device with reduced leakage current over a device with a III-V n-type layer.

A power semiconductor package that includes a semiconductor die having at least two power electrodes and a conductive clip electrically and mechanically coupled to each power electrode.