The present disclosure provides semiconductor structures and fabrication methods thereof. An exemplary fabrication method includes providing a plurality of fins on a semiconductor substrate; forming an anti-diffusion layer, containing anti-diffusion ions, in the fins; forming an anti-punch through layer, containing anti-punch through ions, in the fins, a top surface of the anti-punch through layer being below a top surface of the anti-diffusion layer, and the anti-diffusion layer preventing the anti-punch through ions from diffusing toward tops of the fins; and performing a thermal annealing process.

A method of forming a vertical fin field effect transistor (vertical finFET) with an increased surface area between a source/drain contact and a doped region, including forming a doped region on a substrate, forming one or more interfacial features on the doped region, and forming a source/drain contact on at least a portion of the doped region, wherein the one or more interfacial features increases the surface area of the interface between the source/drain contact and the doped region compared to a flat source/drain contact-doped region interface.

A semiconductor structure includes at least two field effect transistors. A gate strip including a plurality of gate dielectrics and a gate electrode strip can be formed over a plurality of semiconductor active regions. Source/drain implantation is conducted using the gate strip as a mask. The gate strip is divided into gate electrodes after the implantation.

A semiconductor device includes: an n− type layer disposed on a first surface of an n+ type silicon carbide substrate; a first trench and a second trench formed in the n− type layer and separated from each other; an n+ type region disposed between a side surface of the first trench and the side surface of the second trench and disposed on the n− type layer; a gate insulating layer disposed inside the first trench; a source insulating layer disposed inside the second trench; a gate electrode disposed on the gate insulating layer; an oxide layer disposed on the gate electrode; a source electrode disposed on the oxide layer, the n+ type region, and the source insulating layer; and a drain electrode disposed on a second surface of the n+ type silicon carbide substrate.

A structure includes a laterally diffused (LD) MOSFET with an n-type drift region disposed on a surface of a substrate and a p-type body region contained in the drift region. The structure further includes an n-type source region contained in the p-type body region; an n-type drain region contained in the n-type drift region; a gate electrode disposed on a gate dielectric overlying a portion of the p-type body region and the n-type drift region and an electrically conductive field shield member disposed within the n-type drift region at least partially beneath the p-type body region and generally parallel to the gate electrode. The electrically conductive buried field shield member is contained within and surrounded by a layer of buried field shield oxide and is common to both a first LD MOSFET and a second LD MOSFET that are connected in parallel. Methods to fabricate the structure are also disclosed.

A structure includes a laterally diffused (LD) MOSFET with an n-type drift region disposed on a surface of a substrate and a p-type body region contained in the drift region. The structure further includes an n-type source region contained in the p-type body region; an n-type drain region contained in the n-type drift region; a gate electrode disposed on a gate dielectric overlying a portion of the p-type body region and the n-type drift region and an electrically conductive field shield member disposed within the n-type drift region at least partially beneath the p-type body region and generally parallel to the gate electrode. The electrically conductive buried field shield member is contained within and surrounded by a layer of buried field shield oxide and is common to both a first LD MOSFET and a second LD MOSFET that are connected in parallel. Methods to fabricate the structure are also disclosed.

A semiconductor fabrication apparatus includes a source chamber being operable to generate charged particles; and a processing chamber integrated with the source chamber and configured to receive the charged particles from the source chamber. The processing chamber includes a wafer stage being operable to secure and move a wafer, and a laser-charged particles interaction module that further includes a laser source to generate a first laser beam; a beam splitter configured to split the first laser beam into a second laser beam and a third laser beam; and a mirror configured to reflect the third laser beam such that the third laser beam is redirected to intersect with the second laser beam to form a laser interference pattern at a path of the charged particles, and wherein the laser interference pattern modulates the charged particles by in a micron-zone mode for processing the wafer using the modulated charged particles.

A method of splitting off a semiconductor wafer from a semiconductor bottle includes: forming a separation region within the semiconductor boule, the separation region having at least one altered physical property which increases thermo-mechanical stress within the separation region relative to the remainder of the semiconductor boule; and applying an external force to the semiconductor boule such that at least one crack propagates along the separation region and a wafer splits from the semiconductor boule.

The present disclosure relates to a nanowire structure, which includes a substrate with a substrate body and an ion implantation region, a patterned mask with an opening over the substrate, and a nanowire. Herein, the substrate body is formed of a conducting material, and the ion implantation region that extends from a top surface of the substrate body into the substrate body is electrically insulating. A surface portion of the substrate body is exposed through the opening of the patterned mask, while the ion implantation region is fully covered by the patterned mask. The nanowire is directly formed over the exposed surface portion of the substrate body and is not in contact with the ion implantation region. Furthermore, the nanowire is confined within the ion implantation region, such that the ion implantation region is configured to provide a conductivity barrier of the nanowire in the substrate.

The present disclosure relates to a nanowire structure, which includes a substrate with a substrate body and an ion implantation region, a patterned mask with an opening over the substrate, and a nanowire. Herein, the substrate body is formed of a conducting material, and the ion implantation region that extends from a top surface of the substrate body into the substrate body is electrically insulating. A surface portion of the substrate body is exposed through the opening of the patterned mask, while the ion implantation region is fully covered by the patterned mask. The nanowire is directly formed over the exposed surface portion of the substrate body and is not in contact with the ion implantation region. Furthermore, the nanowire is confined within the ion implantation region, such that the ion implantation region is configured to provide a conductivity barrier of the nanowire in the substrate.