A method of growing nanowires includes forming catalyst particles including a gold-indium alloy on portions of a semiconductor substrate that are exposed by openings of a template layer disposed on the substrate, and growing the nanowires including a compound semiconductor material, such as AlP, GaP, etc., under the catalyst particles. The substrate may be reused after removing the nanowires from the substrate.

Provided is a semiconductor light-emitting element having improved light emission output. The semiconductor light-emitting element includes a light-emitting layer having a layered structure in which a first III-V compound semiconductor layer and a second III-V compound semiconductor layer having different composition ratios are repeatedly stacked. The first and second III-V compound semiconductor layers each contain three or more types of elements that are selected from Al, Ga, and In and from As, Sb, and P. The composition wavelength difference between the composition wavelength of the first III-V compound semiconductor layer and the composition wavelength of the second III-V compound semiconductor layer is 50 nm or less. The ratio of the lattice constant difference between the lattice constant of the first III-V compound semiconductor layer and the lattice constant of the second III-V compound semiconductor layer is not less than 0.05% and not more than 0.60%.

This invention is directed toward a method for manufacturing a semiconductor device with a heterostructure comprises covering a semiconductor structure with a seed layer structure; forming one or more separated circularly shaped openings in the seed layer structure to expose the semiconductor structure therein, and leave the seed layer structure outside the one or more separated circularly shaped openings; forming an insulator layer thereon; etching the obtained structure to (i) expose at least a portion of the seed layer structure, such that the exposed at least portion of the seed layer structure surrounds each of the one or more separated circularly shaped openings, and (ii) optionally expose the semiconductor structure, in the one or more separated circularly shaped openings; and epitaxially growing a semiconductor layer from the exposed at least portion of the seed layer structure, firstly mainly vertically and then into each of the one or more separated circularly shaped openings until the epitaxially grown semiconductor layer coalesces with the insulator layer or the semiconductor structure in each of the one or more separated circularly shaped openings.

Methods of forming structures that include InP-based materials, such as a transistor operating as an inversion-type, enhancement-mode device. A dielectric layer may be deposited by ALD over a semiconductor layer including In and P. A channel layer may be formed above a buffer layer having a lattice constant similar to a lattice constant of InP, the buffer layer being formed over a substrate having a lattice constant different from a lattice constant of InP.

A method for forming a multi-stack nanowire device includes forming a common release layer on a substrate, the common release layer comprising a common release material. The method also includes forming a first multi-layer stack on a first portion of the common release layer, the first multi-layer stack comprising at least two layers separated by at least one layer comprising the common release material, and forming a second multi-layer stack on a second portion of the common release layer, the second multi-layer stack comprising at least two layers separated by at least one layer comprising the common release material. The method further includes patterning each of the first multi-layer stack and the second multi-layer stack into one or more fins and forming two or more multi-stack nanowires from the one or more fins by removing the common release material using a common etch process.

A semiconductor device that includes a fin structure of a type III-V semiconductor material that is substantially free of defects, and has sidewalls that are substantially free of roughness caused by epitaxially growing the type III-V semiconductor material abutting a dielectric material. The semiconductor device further includes a gate structure present on a channel portion of the fin structure; and a source region and a drain region present on opposing sides of the gate structure.

An epitaxial wafer which allows manufacture of a photodiode having suppressed dark current and ensured sensitivity, and a method for manufacturing the epitaxial wafer, are provided. The epitaxial wafer of the present invention includes: a III-V semiconductor substrate; and a multiple quantum well structure disposed on the substrate, and including a plurality of pairs of a first layer and a second layer. The total concentration of elements contained as impurities in the multiple quantum well structure is less than or equal to 5×10.sup.15 cm.sup.−3.

An embodiment includes a device comprising: a first epitaxial layer, coupled to a substrate, having a first lattice constant; a second epitaxial layer, on the first layer, having a second lattice constant; a third epitaxial layer, contacting an upper surface of the second layer, having a third lattice constant unequal to the second lattice constant; and an epitaxial device layer, on the third layer, including a channel region; wherein (a) the first layer is relaxed and includes defects, (b) the second layer is compressive strained and the third layer is tensile strained, and (c) the first, second, third, and device layers are all included in a trench. Other embodiments are described herein.

Techniques are provided that can impart sufficient electrical conductivity to a semiconductor crystal exhibiting low doping efficiency for silicon atoms, such as InGaAs, by implanting only a small amount of silicon atoms. Such a semiconductor wafer may include a first semiconductor crystal layer, a second semiconductor crystal layer exhibiting a conductivity type that is different from the first layer, a third semiconductor crystal layer exhibiting the conductivity type of the first layer and having a larger band gap than the second semiconductor crystal layer, and a fourth semiconductor crystal layer exhibiting the conductivity type of the first layer and having a smaller band gap than the third semiconductor crystal layer. The fourth semiconductor crystal layer contains a first element that generates a first carrier of a corresponding conductivity type and a second element that generates a second carrier of a corresponding conductivity type.

Disclosed is a wafer or a material stack for semiconductor-based optoelectronic or electronic devices that minimizes or reduces misfit dislocation, as well as a method of manufacturing such wafer of material stack. A material stack according to the disclosed technology includes a substrate; a basis buffer layer of a first material disposed above the substrate; and a plurality of composite buffer layers disposed above the basis buffer layer sequentially along a growth direction. The growth direction is from the substrate to a last composite buffer layer of the plurality of composite buffer layers. Each composite buffer layer except the last composite buffer layer includes a first buffer sublayer of the first material, and a second buffer sublayer of a second material disposed above the first buffer sublayer. The thicknesses of the first buffer sublayers of the composite buffer layers decrease along the growth direction.