Semiconductor structure and methods for fabricating the same are provided. An example semiconductor structure includes a bulk substrate having a top surface and a silicon-on-insulator (SOI) substrate merged in the bulk substrate. The SOI substrate further includes a heavily doped layer, an insulating layer disposed on and surrounded by the heavily doped layer, and an active substrate disposed on and surrounded by the insulating layer. The semiconductor structure further includes one or more semiconductor devices disposed in the active substrate, a peripheral heavily doped region connected to the heavily doped layer, and a discharging metal structure electrically interconnecting the semiconductor devices to the peripheral heavily doped region.

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.

A method comprises forming a first set of one or more fins in a first region from an insulated substrate and a second set of one or more fins in a second region from the insulated substrate. The insulated substrate comprises a silicon substrate, and an insulator layer deposited on the silicon substrate. The first region comprises a first material layer and the second region comprises a second material layer.

A method comprises forming one or more fins in a first region on an insulated substrate. The method also comprises forming one or more fins formed in a second region on the insulated substrate. The insulated substrate comprising a silicon substrate, and an insulator layer deposited on the silicon substrate. The one or more fins in the first region comprising a first material layer deposited on the insulator layer. The one or more fins in the second region comprising a second material layer deposited on the insulator layer.

A semiconductor structure includes a semiconductor-on-insulator (SOI) substrate including a handle substrate, a buried insulating layer, and a top semiconductor layer; a first deep trench isolation structure that vertically extends through the top semiconductor layer and the buried insulating layer, and includes a first inner insulating liner laterally surrounding a first portion of the top semiconductor layer that is located in a first device region in a plan view, a first non-insulating moat structure laterally surrounding the first inner insulating liner, and a first outer insulating liner that laterally surrounds the first non-insulating moat structure; and a resistive memory array located on the first portion of the top semiconductor layer, and located entirely within the first device region in the plan view.

A semiconductor device includes: a semiconductor substrate; an epitaxial layer or layer stack on the semiconductor substrate; a plurality of transistor cells of a first type formed in a first region of the epitaxial layer or layer stack and electrically coupled in parallel to form a vertical power transistor; a plurality of transistor cells of a second type different than the first type and formed in a second region of the epitaxial layer or layer stack; and an isolation structure that laterally and vertically delimits the second region of the epitaxial layer or layer stack. Sidewalls and a bottom of the isolation structure include a dielectric material that electrically isolates the plurality of transistor cells of the second type from the plurality of transistor cells of the first type in the epitaxial layer or layer stack. Methods of producing the semiconductor device are also described.

A method comprises forming one or more fins in a first region on an insulated substrate. The method also comprises forming one or more fins formed in a second region on the insulated substrate. The insulated substrate comprising a silicon substrate, and an insulator layer deposited on the silicon substrate. The one or more fins in the first region comprising a first material layer deposited on the insulator layer. The one or more fins in the second region comprising a second material layer deposited on the insulator layer.

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.

Structures for a field-effect transistor and methods of forming a structure for a field-effect transistor. The structure comprises a silicon-on-insulator substrate including a semiconductor substrate, a dielectric layer on the semiconductor substrate, and a semiconductor layer on the dielectric layer. The structure further comprises a gate electrode on the semiconductor layer. The gate electrode comprises a single-crystal semiconductor material. The structure further comprises a spacer structure including a first portion that overlaps with a side surface of the dielectric layer and a second portion that overlaps with a portion of the semiconductor substrate adjacent to the side surface of the dielectric layer.

The application discloses a method for forming a hybrid substrate of a SOI wafer. Buried oxide and silicon-on-insulator in some areas are removed, a layer of SiOCN is deposited on a SOI sidewall to protect the silicon-on-insulator sidewall, and then the growth of epitaxial silicon is performed to cause the silicon substrate area to grow to be flush with the silicon-on-insulator area. The SiOCN on the SOI sidewall acts as a protective layer to prevent the growth of epitaxial silicon on the SOI sidewall, thereby preventing the generation of a bulge at a boundary between the SOI area and the silicon substrate area and improving the product yield. Moreover, a SiOCN film may be deposited with high conformality, and the SiOCN deposited on the SOI sidewall has good uniformity, so that the growth of epitaxial Si from the SOI does not occur during subsequent growth of the epitaxial silicon.