The present disclosure provides a semiconductor structure, including: a semiconductor device layer including a first surface and a second surface, wherein the first surface is at a front side of the semiconductor device layer, and the second surface is at a backside of the semiconductor device layer; an insulating layer above the second surface of the semiconductor device; and a through-silicon via (TSV) traversing the insulating layer. Associated manufacturing methods of the same are also provided.

A lift-off method for transferring an optical device layer in an optical device wafer to a transfer substrate, the optical device layer being formed on the front side of an epitaxy substrate through a buffer layer. A transfer substrate is bonded through a bonding layer to the front side of the optical device layer of the optical device wafer, thereby forming a composite substrate. A pulsed laser beam having a wavelength transmissive to the epitaxy substrate and absorptive to the buffer layer is applied from the back side of the epitaxy substrate to the buffer layer, thereby breaking the buffer layer, and the epitaxy substrate is peeled from the optical device layer, thereby transferring the optical device layer to the transfer substrate. Ultrasonic vibration is applied to the composite substrate in transferring the optical device layer.

A semiconductor device, the device including: a plurality of transistors, where at least one of the plurality of transistors includes a first single crystal channel, where at least one of the plurality of transistors includes a second single crystal channel, where the second single crystal channel is disposed above the first single crystal channel, where at least one of the plurality of transistors includes a third single crystal channel, where the third single crystal channel is disposed above the second single crystal channel, where at least one of the plurality of transistors includes a fourth single crystal channel, and where the fourth single crystal channel is disposed above the third single crystal channel; and at least one region of oxide to oxide bonds.

A method of making a semiconductor arrangement includes forming a first layer of molecular ions in a first wafer interface region of a first wafer, forming a second layer of molecular ions in a second wafer interface region of a second wafer, forming a first molecular bond connecting the first wafer interface region to the second wafer interface region by applying pressure to at least one of the first wafer or the second wafer in a direction toward the first wafer interface region and the second wafer interface region, and annealing the first wafer and the second wafer to form a second molecular bond connecting the first wafer interface region to the second wafer interface region.

According to an embodiment, a sensor package includes an electrically insulating substrate including a cavity in the electrically insulating substrate, an ambient sensor, an integrated circuit die embedded in the electrically insulating substrate, and a plurality of conductive interconnect structures coupling the ambient sensor to the integrated circuit die. The ambient sensor is supported by the electrically insulating substrate and arranged adjacent the cavity.

Provided are a method of processing a semiconductor substrate and a method of manufacturing a semiconductor device that uses this method of processing. The method of processing the semiconductor substrate includes: a bonding step in which a supporting plate, which is composed primarily of a material that substantially transmits laser light of prescribed wavelength, and a principal surface of a semiconductor substrate, which is composed primarily of a material that substantially transmits the laser light of the prescribed wavelength, are arranged to face each other in a vacuum and then pressed together in the vacuum with an intermediate layer that includes an amorphous silicon layer interposed therebetween; and a separating step in which, after the laser light is radiated from a side of the supporting plate and the intermediate layer absorbs laser energy, the semiconductor substrate and the supporting plate are separated from each other.

A method for manufacturing a semiconductor device includes: providing a carrier wafer and a silicon carbide wafer; bonding a first side of the silicon carbide wafer to the carrier wafer; splitting the silicon carbide wafer bonded to the carrier wafer into a silicon carbide layer thinner than the silicon carbide wafer and a residual silicon carbide wafer, the silicon carbide layer remaining bonded to the carrier wafer during the splitting; and forming a graphene material on the silicon carbide layer.

A method provides a first substrate supporting an insulator layer having trenches formed therein; filling the trenches using an epitaxial growth process with at least semiconductor material; planarizing tops of the filled trenches; forming a first layer of dielectric material on a resulting planarized surface; inverting the first substrate wafer to place the first layer of dielectric material in contact with a second layer of dielectric material on a second substrate; bonding the first substrate to the second substrate through the first and second layers of dielectric material to form a common layer of dielectric material; and removing the first substrate and a first portion of the filled trenches to leave a second portion of the filled trenches disposed upon the common dielectric layer. The removed first portion of the filled trenches contains dislocation defects. The method then removes the insulator layer to leave a plurality of Fin structures.

A semiconductor device includes a lower wafer including a first substrate, a first dielectric layer that is defined on the first substrate, and a first wiring line that is defined in the first dielectric layer; an upper wafer including a second substrate, an isolation layer that is defined in an upper surface of the second substrate, a second dielectric layer, bonded to an upper surface of the first dielectric layer, that covers a lower surface of the second substrate and that includes at least one portion defined in the lower surface of the second substrate below and in contact with the isolation layer, and a third dielectric layer that is defined on the upper surface of the second substrate, and a second wiring line that is defined on the third dielectric layer; and a through via passing through, under the second wiring line, the third dielectric layer, the isolation layer, the second dielectric layer under the isolation layer and the first dielectric layer, and coupling the second wiring line and the first wiring line.

A method of transferring a thin film from a substrate to a flexible support that includes transfer of the flexible support by a layer of polymer, crosslinkable under ultraviolet light, directly on the thin film, the adhesion energy of the polymer evolving according to its degree of crosslinking, decreasing to an energy point d minimum adhesion achieved for a nominal crosslinking rate, then increasing for a crosslinking rate greater than the nominal crosslinking rate, then apply, on the polymer layer, an ultraviolet exposure parameterized so as to stiffen the polymer layer and have an adhesion energy between the thin film and the flexible support greater than an adhesion energy between the thin film and the substrate, then remove the substrate.