The invention relates to a method for fabricating a semiconductor circuit comprising providing a semiconductor substrate; fabricating a first semiconductor device comprising a first semiconductor material on the substrate and forming an insulating layer comprising a cavity structure on the first semiconductor device. The cavity structure comprises at least one growth channel and the growth channel connects a crystalline seed surface of the first semiconductor device with an opening. Further steps include growing via the opening from the seed surface a semiconductor filling structure comprising a second semiconductor material different from the first semiconductor material in the growth channel; forming a semiconductor starting structure for a second semiconductor device from the filling structure; and fabricating a second semiconductor device comprising the starting structure. The invention is notably also directed to corresponding semiconductor circuits.

Technologies are generally described for operating and manufacturing optomechanical accelerometers. In some examples, an optomechanical accelerometer device is described that uses a cavity resonant displacement sensor based on a zipper photonic crystal nano-cavity to measure the displacement of an integrated test mass generated by acceleration applied to the chip. The cavity-resonant sensor may be fully integrated on-chip and exhibit an enhanced displacement resolution due to its strong optomechanical coupling. The accelerometer structure may be fabricated in a silicon nitride thin film and constitute a rectangular test mass flexibly suspended on high aspect ratio inorganic nitride nano-tethers under high tensile stress. By increasing the mechanical Q-factors through adjustment of tether width and tether length, the noise-equivalent acceleration (NEA) may be reduced, while maintaining a large operation bandwidth. The mechanical Q-factor may be improved with thinner (e.g., <1 micron) and longer tethers (e.g., 10-560 microns).

According to an embodiment of a method of fabricating III-Nitride semiconductor dies, the method includes: growing a III-Nitride body over a group IV substrate in a semiconductor wafer; forming at least one device layer over the III-Nitride body; etching grid array trenches in the III-Nitride body and in the group IV substrate; forming an edge trench around a perimeter of the semiconductor wafer, the grid array trenches terminating inside the group IV substrate; and forming separate dies by cutting the semiconductor wafer approximately along the grid array trenches.

Embodiment methods for performing a high pressure anneal process during the formation of a semiconductor device, and embodiment devices therefor, are provided. The high pressure anneal process may be a dry high pressure anneal process in which a pressurized environment of the anneal includes one or more process gases. The high pressure anneal process may be a wet anneal process in which a pressurized environment of the anneal includes steam.

A process for transferring a useful layer to a receiver substrate includes providing a donor substrate comprising an intermediate layer, a carrier substrate, and a useful layer. The intermediate layer is free of species liable to degas during a subsequent heat treatment, and is configured to become soft at a temperature. The receiver substrate and the donor substrate are assembled. An additional layer is provided between the receiver substrate and the carrier substrate that comprises chemical species that are susceptible to diffuse into the intermediate layer during the subsequent heat treatment so as to form a weak zone. The heat treatment is carried out on the receiver substrate and the donor substrate at a second temperature higher than the first temperature.

The present disclosure provides a semiconductor device and a method of forming the same. A method according one embodiment of the present disclosure includes forming a first stack over a substrate and a second stack over the first stack. The first stack includes semiconductor layers interleaved by dielectric layers. The second stack includes channel layers interleaved by sacrificial layers. The method also includes patterning the second stack to form a fin-shape structure, recessing a portion of the fin-shape structure to form a recess exposing a top surface of the first stack, epitaxially growing an epitaxial feature directly from the top surface of the first stack, removing the sacrificial layers to release the channel layers, and forming a gate structure wrapping around each of the channel layers.

The present disclosure provides a semiconductor device and a method of forming the same. A method according one embodiment of the present disclosure includes forming a first stack over a substrate and a second stack over the first stack. The first stack includes semiconductor layers interleaved by dielectric layers. The second stack includes channel layers interleaved by sacrificial layers. The method also includes patterning the second stack to form a fin-shape structure, recessing a portion of the fin-shape structure to form a recess exposing a top surface of the first stack, epitaxially growing an epitaxial feature directly from the top surface of the first stack, removing the sacrificial layers to release the channel layers, and forming a gate structure wrapping around each of the channel layers.