Structures with altered crystallinity beneath semiconductor devices and methods associated with forming such structures. Trench isolation regions surround an active device region composed of a single-crystal semiconductor material. A first non-single-crystal layer is arranged beneath the trench isolation regions and the active device region. A second non-single-crystal layer is arranged beneath the trench isolation regions and the active device region. The first non-single-crystal layer is arranged between the second non-single-crystal layer and the active device region.

A semiconductor structure and a method for forming the same are provided. The semiconductor structure includes a gate structure formed over a fin structure, and a source/drain (S/D) epitaxial layer formed in the fin structure and adjacent to the gate structure. The S/D epitaxial layer includes a first S/D epitaxial layer and a second epitaxial layer. The semiconductor structure includes a gate spacer formed on a sidewall surface of the gate structure, and the gate spacer is directly over the first S/D epitaxial layer. The semiconductor structure includes a dielectric spacer formed adjacent to the gate spacer, and the dielectric spacer is directly over the second epitaxial layer.

Gate-all-around integrated circuit structures having vertically discrete source or drain structures, and methods of fabricating gate-all-around integrated circuit structures having vertically discrete source or drain structures, are described. For example, an integrated circuit structure includes a vertical arrangement of horizontal nanowires. A gate stack is around the vertical arrangement of horizontal nanowires. A first epitaxial source or drain structure is at a first end of the vertical arrangement of horizontal nanowires, the first epitaxial source or drain structure including vertically discrete portions aligned with the vertical arrangement of horizontal nanowires. A second epitaxial source or drain structure is at a first end of the vertical arrangement of horizontal nanowires, the second epitaxial source or drain structure including vertically discrete portions aligned with the vertical arrangement of horizontal nanowires.

An integrated circuit structure comprises a silicon substrate and a III-nitride (III-N) substrate over the silicon substrate. A first III-N transistor and a second III-N transistor is on the III-N substrate. An insulator structure is formed in the III-N substrate between the first III-N transistor and the second III-N, wherein the insulator structure comprises one of: a shallow trench filled with an oxide, nitride or low-K dielectric; or a first gap adjacent to the first III-N transistor and a second gap adjacent to the second III-N transistor.

A semiconductor structure includes at least one stacked fin structure, a gate and a source/drain. At least one stacked fin structure is located on a substrate, wherein the stacked fin structure includes a first fin layer and a second fin layer, and a fin dielectric layer is sandwiched by the first fin layer and the second fin layer. The gate is disposed over the stacked fin structure. The source/drain is disposed directly on the substrate and directly on sidewalls of the whole stacked fin structure. The present invention provides a semiconductor process formed said semiconductor structure.

Embodiments of the invention are directed to a fabrication method that includes forming a first-region channel over a first region of a substrate, wherein the first-region channel further includes lateral sidewalls having a length (L), a first end sidewall having a first width (W1), and a second end sidewall having a second width (W2). L is greater than W1, and L is greater than W2. A first stress anchor is formed on the first end sidewall of the first-region channel, and a second stress anchor is formed on the second end sidewall of the first-region channel. The first stress anchor is configured to impart strain through the first end sidewalls to the first-region channel. The second stress anchor is configured to impart strain through the second end sidewalls to the first-region channel.

Integrated circuit structures having cut metal gates, and methods of fabricating integrated circuit structures having cut metal gates, are described. For example, an integrated circuit structure includes a fin having a portion protruding above a shallow trench isolation (STI) structure. A gate dielectric material layer is over the protruding portion of the fin and over the STI structure. A conductive gate layer is over the gate dielectric material layer. A conductive gate fill material is over the conductive gate layer. A dielectric gate plug is laterally spaced apart from the fin, the dielectric gate plug on but not through the STI structure. The gate dielectric material layer and the conductive gate layer are not along sides of the dielectric gate plug, and the conductive gate fill material is in contact with the sides of the dielectric gate plug.

Provided is a semiconductor device in which a leakage current is reduced, the semiconductor device which is particularly useful for power devices. A semiconductor device including at least: an n+-type semiconductor layer, which contains a crystalline oxide semiconductor as a major component; an n−-type semiconductor layer that is placed on the n+-type semiconductor layer, the n−-type semiconductor layer containing a crystalline oxide semiconductor as a major component; a high-resistance layer with at least a part thereof being embedded in the n−-type semiconductor layer, a depth d (μm) of the part embedded in the n−-type semiconductor layer satisfying d≥1.4; and a Schottky electrode that forms a Schottky junction with the n−-type semiconductor layer, the Schottky electrode having an edge located on the high-resistance layer.

Provided is a semiconductor device in which a leakage current is reduced, the semiconductor device which is particularly useful for power devices. A semiconductor device including at least: an n+-type semiconductor layer, which contains a crystalline oxide semiconductor as a major component; an n−-type semiconductor layer that is placed on the n+-type semiconductor layer, the n−-type semiconductor layer containing a crystalline oxide semiconductor as a major component; a high-resistance layer with at least a part thereof being embedded in the n−-type semiconductor layer, the high-resistance layer having a bottom surface located at a distance of less than 1.5 μm from an upper surface of the n+-type semiconductor layer; and a Schottky electrode that forms a Schottky junction with the n−-type semiconductor layer, the Schottky electrode having an edge located on the high-resistance layer.

An anti-fuse having two electrical connections is constructed by adding at least one zener diode and resistor to a power MOSFET. When the voltage across the two electrical connections exceeds the zener diode voltage and the maximum gate voltage of the MOSFET, the MOSFET burns out. This shorts out the device which can be used to bypass an LED or other load when that load burns out and forms an open circuit.