A semiconductor structure is provided by a process in which two aspect ratio trapping processes are employed. The structure includes a semiconductor substrate portion of a first semiconductor material having a first lattice constant. A plurality of first semiconductor-containing pillar structures of a second semiconductor material having a second lattice constant that is greater than the first lattice constant extend upwards from a surface of the semiconductor substrate portion. A plurality of second semiconductor-containing pillar structures of a third semiconductor material having a third lattice constant that is greater than the first lattice constant extend upwards from another surface of the semiconductor substrate portion. A spacer separates each first semiconductor-containing pillar structure from each second semiconductor-containing pillar structure. Each second semiconductor-containing pillar structure has a width that is different from a width of each first semiconductor-containing pillar structure.

Provided is an oxide with a novel crystal structure, an oxide with high crystallinity, or an oxide with low impurity concentration. An oxide has a hexagonal atomic arrangement in the case of a single crystal. The oxide has a homologous structure of indium, an element M (aluminum, gallium, yttrium, or tin), and zinc. The oxide has a lattice point group observed through an analysis of a first region in a transmission electron microscopy image of a top surface of the oxide. In a Voronoi diagram having a plurality of Voronoi regions obtained through a Voronoi analysis of the lattice point group, a proportion of hexagonal Voronoi regions is higher than or equal to 78% and lower than or equal to 100%.

In one embodiment, a group III-V transistor structure includes a heterostructure disposed on a semiconductor substrate. A first current carrying electrode and a second current carrying electrode are disposed adjacent a major surface of the heterostructure and a control electrode is disposed between the first and second current carrying electrode. A clamping device is integrated with the group III-V transistor structure and is electrically connected to the first current carrying electrode a third electrode to provide a secondary current path during, for example, an electrical stress event.

After forming a seed layer over a first end of a sacrificial semiconductor layer composed of silicon germanium, a remaining portion of the sacrificial semiconductor layer is removed to provide a trench. Next, a semiconductor barrier layer is formed on a sidewall of the seed layer that is exposed by the trench. A III-V compound semiconductor layer is formed within the trench by a lateral epitaxial semiconductor regrowth process.

To provide a semiconductor device with excellent electrical characteristics or a semiconductor device with stable electrical characteristics. A semiconductor device includes a first transistor, a second transistor, a first insulator, a second insulator, a first wiring, and a first plug. The first transistor includes silicon. The second transistor includes an oxide semiconductor. The first insulator is located over the first transistor. The second insulator is located over the first insulator. The second transistor is located over the second insulator. The first wiring is located over the second insulator and the first plug. The first transistor and the second transistor are electrically connected to each other through the first wiring and the first plug. The first wiring has low hydrogen permeability. The hydrogen permeability of the second insulator is lower than the hydrogen permeability of the first insulator.

In one embodiment, a method of forming a semiconductor device includes forming openings in a substrate. The method includes forming a dummy fill material within the openings and thinning the substrate to expose the dummy fill material. The dummy fill material is removed.

To provide a semiconductor device which occupies a small area and is highly integrated. The semiconductor device includes an oxide semiconductor layer, an electrode layer, and a contact plug. The electrode layer includes one end portion in contact with the oxide semiconductor layer and the other end portion facing the one end portion. The other end portion includes a semicircle notch portion when seen from the above. The contact plug is in contact with the semicircle notch portion.

In one example, a method for fabricating a semiconductor device includes forming a mandrel comprising silicon. Sidewalls of the silicon are orientated normal to the <111> direction of the silicon. A nanowire is grown directly on at least one of the sidewalls of the silicon and is formed from a material selected from Groups III-V. Only one end of the nanowire directly contacts the silicon.

Architectures and techniques for co-integration of heterogeneous materials, such as group III-V semiconductor materials and group IV semiconductors (e.g., Ge) on a same substrate (e.g. silicon). In embodiments, multi-layer heterogeneous semiconductor material stacks having alternating nanowire and sacrificial layers are employed to release nanowires and permit formation of a coaxial gate structure that completely surrounds a channel region of the nanowire transistor. In embodiments, individual PMOS and NMOS channel semiconductor materials are co-integrated with a starting substrate having a blanket layers of alternating Ge/III-V layers. In embodiments, vertical integration of a plurality of stacked nanowires within an individual PMOS and individual NMOS device enable significant drive current for a given layout area.

A method of forming a semiconductor structure is provided. The method includes providing a substrate comprising, from bottom to top, a handle substrate, an insulator layer and a germanium-containing layer. Next, hard mask material portions having an opening that exposes a portion of the germanium-containing layer are formed on the substrate. An etch is then performed through the opening to provide an undercut region in the germanium-containing layer. A III-V compound semiconductor material is grown within the undercut region by utilizing an aspect ratio trapping growth process. Next, portions of the III-V compound semiconductor material are removed to provide III-V compound semiconductor material portions located between remaining portions of the germanium-containing layer.