Embodiments of the present disclosure may generally relate to systems, apparatus, and/or processes to form volumes of oxide within a fin, such as a Si fin. In embodiments, this may be accomplished by applying a catalytic oxidant material on a side of a fin and then annealing to form a volume of oxide. In embodiments, this may be accomplished by using a plasma implant technique or a beam-line implant technique to introduce oxygen ions into an area of the fin and then annealing to form a volume of oxide. Processes described here may be used manufacture a transistor, a stacked transistor, or a three-dimensional (3-D) monolithic stacked transistor.

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.

In accordance with an embodiment, a method for producing a buried cavity structure includes providing a mono-crystalline semiconductor substrate, producing a doped volume region in the mono-crystalline semiconductor substrate, wherein the doped volume region has an increased etching rate for a first etchant by comparison with an adjoining, undoped or more lightly doped material of the monocrystalline semiconductor substrate, forming an access opening to the doped volume region, and removing the doped semiconductor material in the doped volume region using the first etchant through the access opening to obtain the buried cavity structure.

Structures with altered crystallinity beneath semiconductor devices and methods associated with forming such structures. A semiconductor layer is implanted over a first depth range of an inert gas species to modify the crystal structure of a semiconductor material of the semiconductor layer and form a first modified region. The semiconductor layer is annealed with a first annealing process to convert the semiconductor material within the first modified region to a non-single-crystal layer. The semiconductor layer is also implanted with ions of an element over a second depth range to modify the crystal structure of the semiconductor material of the semiconductor layer and form a second modified region containing a concentration of the element. The semiconductor layer is annealed with a second annealing process to convert the semiconductor material within the second modified region to an insulator layer containing the element.

Structures with altered crystallinity beneath semiconductor devices and methods associated with forming such structures. A semiconductor layer is implanted over a first depth range of an inert gas species to modify the crystal structure of a semiconductor material of the semiconductor layer and form a first modified region. The semiconductor layer is annealed with a first annealing process to convert the semiconductor material within the first modified region to a non-single-crystal layer. The semiconductor layer is also implanted with ions of an element over a second depth range to modify the crystal structure of the semiconductor material of the semiconductor layer and form a second modified region containing a concentration of the element. The semiconductor layer is annealed with a second annealing process to convert the semiconductor material within the second modified region to an insulator layer containing the element.

A device fabricated on a wafer is disclosed. The device includes a first block of the wafer and a second block of the wafer isolated from the first block using a first deep trench isolation (DTI). The device further includes a third block of the wafer isolated from the second block using a second DTI. The second block includes a first vertical section coupled to a first ground, a second vertical section, a third vertical section coupled to a second ground. The second vertical section is doped lightly compared to the first vertical section and the second vertical section.

Semiconductor structures and methods of forming semiconductor structures. Trench isolation regions arranged to surround an active device region The trench isolation regions extend through a device layer and a buried oxide layer of a silicon-on-insulator wafer into a substrate of the silicon-on-insulator wafer. A well is arranged in the substrate outside of the trench isolation regions, and a doped region is arranged in a portion of the substrate. The doped region is arranged in a portion of the substrate that is located in a horizontal direction adjacent to one of the trench isolation regions and in a vertical direction adjacent to the buried oxide layer. The doped region and the well have the same conductivity type.

A method includes forming a first semiconductor fin and a second semiconductor fin parallel to each other and protruding higher than top surfaces of isolation regions. The isolation regions include a portion between the first and the second semiconductor fins. The method further includes forming a gate stack crossing over the first and the second semiconductor fins, etching a portion of the gate stack to form an opening, wherein the portion of the isolation regions, the first semiconductor fin, and the second semiconductor fin are exposed to the opening, etching the first semiconductor fin, the second semiconductor fin, and the portion of the isolation regions to extend the opening into a bulk portion of a semiconductor substrate below the isolation regions, and filling the opening with a dielectric material to form a cut-fin isolation region.

A device fabricated on a wafer is disclosed. The device includes a first block of the wafer and a second block of the wafer isolated from the first block using a first deep trench isolation (DTI). The device further includes a third block of the wafer isolated from the second block using a second DTI. The second block includes a first vertical section coupled to a first ground, a second vertical section, a third vertical section coupled to a second ground. The second vertical section is doped lightly compared to the first vertical section and the second vertical section.

In accordance with an embodiment of an integrated circuit, a cavity is buried in a semiconductor body below a first surface of the semiconductor body. An active area portion of the semiconductor body is arranged between the first surface and the cavity. The integrated circuit further includes a trench isolation structure configured to provide a lateral electric isolation of the active area portion.