Semiconductor device fabrication method and structures are provided having a substrate structure which includes a silicon layer at an upper portion. The silicon layer is recessed in a first region of the substrate structure and remains unrecessed in a second region of the substrate structure. A protective layer having a first germanium concentration is formed above the recessed silicon layer in the first region, which extends along a sidewall of the unrecessed silicon layer of the second region. A semiconductor layer having a second germanium concentration is disposed above the protective layer in the first region of the substrate structure, where the first germanium concentration of the protective layer inhibits lateral diffusion of the second germanium concentration from the semiconductor layer in the first region into the unrecessed silicon layer in the second region of the substrate structure.

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.

A semiconductor structure is provided that includes a plurality of suspended and stacked nanosheets of semiconductor channel material located above a pillar of a sacrificial III-V compound semiconductor material. Each semiconductor channel material comprises a semiconductor material that is substantially lattice matched to, but different from, the sacrificial III-V compound semiconductor material, and each suspended and stacked nanosheets of semiconductor channel material has a chevron shape. A functional gate structure can be formed around each suspended and stacked nanosheet of semiconductor channel material.

A fuse structure is provided above a first portion of a semiconductor material. The fuse structure includes a first end region containing a first portion of a metal structure having a first thickness, a second end region containing a second portion of the metal structure having the first thickness, and a neck region located between the first and second end regions. The neck region contains a third portion of the metal structure having a second thickness that is less than the first thickness, wherein a portion of the neck region is located in a gap positioned between a bottom III-V compound semiconductor material portion and a top III-V compound semiconductor material portion.

A group III-N nanowire is disposed on a substrate. A longitudinal length of the nanowire is defined into a channel region of a first group III-N material, a source region electrically coupled with a first end of the channel region, and a drain region electrically coupled with a second end of the channel region. A second group III-N material on the first group III-N material serves as a charge inducing layer, and/or barrier layer on surfaces of nanowire. A gate insulator and/or gate conductor coaxially wraps completely around the nanowire within the channel region. Drain and source contacts may similarly coaxially wrap completely around the drain and source regions.

A crystalline base substrate including a first semiconductor material and having a main surface is provided. The base substrate is processed so as to damage a lattice structure of the base substrate in a first region that extends to the main surface without damaging a lattice structure of the base substrate in second regions that are adjacent to the first region. A first semiconductor layer of a second semiconductor material is formed on a portion of the main surface that includes the first and second regions. A third region of the first semiconductor layer covers the first region of the base substrate, and a fourth region of the first semiconductor layer covers the second region of the base substrate. The third region has a crystalline structure that is disorganized relative to a crystalline structure of the fourth region. The first and second semiconductor materials have different coefficients of thermal expansion.

A method of forming a vertical finFET and vertical diode device on the same substrate, including forming a channel layer stack on a heavily doped layer; forming fin trenches in the channel layer stack; oxidizing at least a portion of the channel layer stack inside the fin trenches to form a dummy layer liner; forming a vertical fin in the fin trenches with the dummy layer liner; forming diode trenches in the channel layer stack; oxidizing at least a portion of the channel layer stack inside the diode trenches to form a dummy layer liner; forming a first semiconductor segment in a lower portion of the diode trenches with the dummy layer liner; and forming a second semiconductor segment in an upper portion of the diode trenches with the first semiconductor segment, where the second semiconductor segment is formed on the first semiconductor segment to form a p-n junction.

A method of forming a vertical finFET and vertical diode device on the same substrate, including forming a channel layer stack on a heavily doped layer; forming fin trenches in the channel layer stack; oxidizing at least a portion of the channel layer stack inside the fin trenches to form a dummy layer liner; forming a vertical fin in the fin trenches with the dummy layer liner; forming diode trenches in the channel layer stack; oxidizing at least a portion of the channel layer stack inside the diode trenches to form a dummy layer liner; forming a first semiconductor segment in a lower portion of the diode trenches with the dummy layer liner; and forming a second semiconductor segment in an upper portion of the diode trenches with the first semiconductor segment, where the second semiconductor segment is formed on the first semiconductor segment to form a p-n junction.

A method of forming a vertical finFET and vertical diode device on the same substrate, including forming a channel layer stack on a heavily doped layer; forming fin trenches in the channel layer stack; oxidizing at least a portion of the channel layer stack inside the fin trenches to form a dummy layer liner; forming a vertical fin in the fin trenches with the dummy layer liner; forming diode trenches in the channel layer stack; oxidizing at least a portion of the channel layer stack inside the diode trenches to form a dummy layer liner; forming a first semiconductor segment in a lower portion of the diode trenches with the dummy layer liner; and forming a second semiconductor segment in an upper portion of the diode trenches with the first semiconductor segment, where the second semiconductor segment is formed on the first semiconductor segment to form a p-n junction.

In a semiconductor device including a transistor, the transistor is provided over a first insulating film, and the transistor includes an oxide semiconductor film over the first insulating film, a gate insulating film over the oxide semiconductor film, a gate electrode over the gate insulating film, a second insulating film over the oxide semiconductor film and the gate electrode, and a source and a drain electrodes electrically connected to the oxide semiconductor film. The first insulating film includes oxygen. The second insulating film includes hydrogen. The oxide semiconductor film includes a first region in contact with the gate insulating film and a second region in contact with the second insulating film. The first insulating film includes a third region overlapping with the first region and a fourth region overlapping with the second region. The impurity element concentration of the fourth region is higher than that of the third region.