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.

The invention provides the use of at least one binary group 15 element compound of the general formula R.sup.1R.sup.2E-E′R.sup.3R.sup.4 (I) or R.sup.5E(E′R.sup.6R.sup.7)2 (II) as the educt in a vapor deposition process. In this case, R.sup.1, R.sup.2, R.sup.3 and R.sup.4 are independently selected from the group consisting of H, an alkyl radical (C1-C10) and an aryl group, and E and E′ are independently selected from the group consisting of N, P, As, Sb and Bi. This use excludes hydrazine and its derivatives. The binary group 15 element compounds according to the invention allow the realization of a reproducible production and/or deposition of multinary, homogeneous and ultrapure 13/15 semiconductors of a defined combination at relatively low process temperatures. This makes it possible to completely waive the use of an organically substituted nitrogen compound such as 1.1 dimethyl hydrazine as the nitrogen source, which drastically reduces nitrogen contaminations—compared to the 13/15 semiconductors and/or 13/15 semiconductor layers produced with the known production methods.

A semiconductor structure and method for manufacturing thereof are provided. The semiconductor structure includes a silicon substrate having a first surface, a III-V layer on the first surface of the silicon substrate and over a first active region, and an isolation region in a portion of the III-V layer extended beyond the first active region. The first active region is in proximal to the first surface. The method includes the following operations. A silicon substrate having a first device region and a second device region is provided, a first active region is defined in the first device region, a III-V layer is formed on the silicon substrate, an isolation region is defined across a material interface in the III-V layer by an implantation operation, and an interconnect penetrating through the isolation region is formed.

A semiconductor substrate is a provided and an insulating layer is formed thereon. A cavity structure is formed above the insulating layer, including a lateral growth channel and a fin seed structure arranged in the lateral growth channel. The fin seed structure provides a seed surface for growing a fin structure. One or more first semiconductor structures of a first semiconductor material and one or more second semiconductor structures of a second, different, semiconductor material are grown sequentially in the growth channel from the seed surface in an alternating way. The first semiconductor structures provide a seed surface for the second semiconductor structures and the second semiconductor structures provide a seed surface for the first semiconductor structures. The second semiconductor structures are selectively etched, thereby forming the fin structure comprising a plurality of parallel fins of the first semiconductor structures. Corresponding semiconductor structures are also included.

Techniques are disclosed for forming integrated circuits configured with self-aligned isolation walls and alternate channel materials. The alternate channel materials in such integrated circuits provide improved carrier mobility through the channel. In an embodiment, an isolation wall is between sets of fins, at least some of the fins including an alternate channel material. In such cases, the isolation wall laterally separates the sets of fins, and the alternate channel material provides improved carrier mobility. For instance, in the case of an NMOS device the alternate channel material is a material optimized for electron flow, and in the case of a PMOS device the alternate channel material is a material optimized for hole flow.

Methods of doping a semiconductor film are provided. The methods comprise epitaxially growing the III-V semiconductor film in the presence of a dopant, a surfactant capable of acting as an electron reservoir, and hydrogen, under conditions that promote the formation of a III-V semiconductor film doped with the p-type dopant. In some embodiments of the methods, the epitaxial growth of the doped III-V semiconductor film is initiated at a first hydrogen partial pressure which is increased to a second hydrogen partial pressure during the epitaxial growth process.

A structure includes a substrate having a first semiconductor material. The substrate has a recess. A bottom portion of the recess has a first sidewall and a second sidewall. The first sidewall intersects the second sidewall. The structure further includes an isolation feature surrounding the recess and a second semiconductor material disposed in the recess and in contact with the first semiconductor material. The second semiconductor material has lattice mismatch to the first semiconductor material.

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.

A method of growing a III-V semiconductor compound film for a semiconductor device including the steps of depositing a textured oxide buffer layer on an inexpensive substrate, depositing a metal-inorganic film from a eutectic alloy on the buffer layer, the metal being a component of a III-V compound and forming a layer on the inorganic film on which additional elements from the III-V compound are added, forming a top layer of a tandem solar cell.

A field effect transistor according to the present invention includes a semiconductor layer including a groove, an insulating film formed on an upper surface of the semiconductor layer and having an opening above the groove and a gate electrode buried in the opening to be in contact with side surfaces and a bottom surface of the groove and having parts being in contact with an upper surface of the insulating film on both sides of the opening, wherein the gate electrode has a T-shaped sectional shape in which a width of an upper end is larger than a width of the upper surface of the insulating film.