A fin transistor structure is provided. The fin transistor structure includes a first substrate. An insulation layer is disposed on the first substrate. A plurality of fin structures are disposed on the insulation layer. A supporting dielectric layer fixes the fin structures at the fin structures at waist parts thereof. A gate structure layer is disposed on the supporting dielectric layer and covers a portion of the fin structures.

The present disclosure relates to integrated circuits which include various structural elements designed to reduce the impact of strain on the electronic components of the circuit. In particular, a combination of trenches and cavities are used to mechanically isolate the integrated circuit from the surrounding substrate. The trenches may be formed such that they surround the integrated circuit, and the cavities may be formed under the integrated circuit. As such, the integrated circuit may be formed on a portion of the substrate that forms a platform. In order that the platform does not move, it may be tethered to the surrounding substrate. By including such mechanical elements, variation in the electrical characteristics of the integrated circuit are reduced.

A semiconductor isolation structure includes a handle layer, a buried insulation layer, a semiconductor layer, a deep trench isolation structure, and a heavy doping region. The buried insulation layer is disposed on the handle layer. The semiconductor layer is disposed on the buried insulation layer and has a doping type. The semiconductor layer has a functional area in which doped regions of a semiconductor device are to be formed. The deep trench isolation structure penetrates the semiconductor layer and the buried insulation layer, and surrounds the functional area. The heavy doping region is formed in the semiconductor layer, is disposed between the functional area and the deep trench isolation structure, and is surrounded by the deep trench isolation structure. The heavy doping region has the doping type. A doping concentration of the heavy doping region is higher than that of the semiconductor layer.

The present disclosure relates to semiconductor structures and, more particularly, to a semiconductor on insulator substrate with cavity structures and methods of manufacture. The structure includes: a bulk substrate with at least one rectilinear cavity structure; an insulator material sealing the at least one rectilinear cavity structure; and a buried insulator layer on the bulk substrate and over the at least one rectilinear cavity structure.

The present disclosure relates to semiconductor structures and, more particularly, to a wafer with localized cavity structures and methods of manufacture. A structure includes a bulk substrate with localized semiconductor on insulator (SOI) regions and bulk device regions, the localized SOI regions includes multiple cavity structures and substrate material of the bulk substrate.

The present disclosure describes a fabrication method that can form air-gaps in shallow trench isolation structures (STI) structures. For example, the method includes patterning a semiconductor layer over a substrate to form semiconductor islands and oxidizing the sidewall surfaces of the semiconductor islands to form first liners on the sidewall surfaces. Further, the method includes depositing a second liner over the first liners and the substrate and depositing a first dielectric layer between the semiconductor islands. The second liner between the first dielectric layer and the first liners is removed to form openings between the first dielectric layer and the first liners. A second dielectric layer is deposited over the first dielectric layer to enclose the openings and form air-gaps between the first dielectric layer and the first liners so that the gaps are positioned along the first liners.

In radio-frequency (RF) devices integrated on semiconductor-on-insulator (e.g., silicon-based) substrates, RF losses may be reduced by increasing the resistivity of the semiconductor device layer in the vicinity of (e.g., underneath and/or in whole or in part surrounding) the metallization structures of the RF device, such as, e.g., transmission lines, contacts, or bonding pads. Increased resistivity can be achieved, e.g., by ion-implantation, or by patterning the device layer to create disconnected semiconductor islands.

A semiconductor structure and a method for manufacturing the same are disclosed. The semiconductor structure includes a semiconductor substrate, a multi-layer stack, a switch device, and an air void. The multi-layer stack is buried in the semiconductor substrate. The multi-layer stack includes a first filling layer and a second filling layer under the first filling layer, the first filling layer has a first etching rate, the second filling layer has a second etching rate, and the first etching rate and the second etching rate are different. The switch device is disposed over the semiconductor substrate. The air void is formed in the multi-layer stack and under the switch device. The air void is surrounded by dielectric filling material.

A method for forming a semiconductor structure includes: providing a substrate; forming a stacked structure on the substrate; forming a barrier layer on a sidewall of the stacked structure; forming a first dielectric layer covering the barrier layer and the stacked structure; removing a portion of the first dielectric layer to expose an upper portion of the stacked structure; forming a metal layer covering the stacked structure and the first dielectric layer; performing an annealing process to react the metal layer with the stacked structure to form a metal silicide layer at the upper portion of the stacked structure; removing an unreacted portion of the metal layer; removing a portion of the barrier layer to form a recess above the barrier layer; and forming a second dielectric layer covering the metal silicide layer and the first dielectric layer to form air gaps on both sides of the stacked structure.

A semiconductor structure includes a first field-effect transistor disposed on a substrate. The first field-effect transistor includes a first metal gate, and a first source/drain region. A second field-effect transistor is vertically stacked above the first field-effect transistor. The second field-effect transistor includes a second metal gate, and a second source/drain region. The first metal gate and the second metal gate are vertically aligned and configured with an air gap disposed therebetween. The first source/drain region and the second source/drain region are vertically aligned and configured with another air gap disposed therebetween.