A detachable structure comprises a carrier substrate and a silicon oxide layer positioned on the substrate at a first interface. The detachable structure is notable in that: the oxide layer has a thickness of less than 200 nm; light hydrogen and/or helium species are distributed deeply and over the entire area of the structure according to an implantation profile, a maximum concentration of which is located in the thickness of the oxide layer; the total dose of implanted light species, relative to the thickness of the oxide layer, exceeds, at least by a factor of five, the solubility limit of these light species in the oxide layer.

A radiofrequency device includes a buried insulation layer, a transistor, a contact structure, a connection bump, an interlayer dielectric layer, and a mold compound layer. The buried insulation layer has a first side and a second side opposite to the first side in a thickness direction of the buried insulation layer. The transistor is disposed on the first side of the buried insulation layer. The contact structure penetrates the buried insulation layer and is electrically connected with the transistor. The connection bump is disposed on the second side of the buried insulation layer and electrically connected with the contact structure. The interlayer dielectric layer is disposed on the first side of the buried insulation layer and covers the transistor. The mold compound layer is disposed on the interlayer dielectric layer. The mold compound layer may be used to improve operation performance and reduce manufacturing cost of the radiofrequency device.

Aspects described herein include a method comprising bonding a photonic wafer with an electronic wafer to form a wafer assembly, removing a substrate of the wafer assembly to expose a surface of the photonic wafer or of the electronic wafer, forming electrical connections between metal layers of the photonic wafer and metal layers of the electronic wafer, and adding an interposer wafer to the wafer assembly by bonding the interposer wafer with the wafer assembly at the exposed surface. The interposer wafer comprises through-vias that are electrically coupled with the metal layers of one or both of the photonic wafer and the electronic wafer. The method further comprises dicing the wafer assembly to form a plurality of dies. A respective edge coupler of each die is optically exposed at an interface formed by the dicing.

A semiconductor structure includes a semiconductor substrate, an oxide layer disposed over the semiconductor substrate, a high-k metal gate structure (HKMG) interleaved with the stack of semiconductor layers, and an epitaxial source/drain (S/D) feature disposed adjacent to the HKMG, wherein a bottom portion of the epitaxial S/D feature is defined by the oxide layer.

A D-type flip-flop circuit 1 has a structure in which a pMOS transistor p8 and an nMOS transistor n8 are added to a general D-type flip-flop circuit comprising pMOS transistors p1 to p7, p11 to p15 and nMOS transistors n1 to n7, n11 to n15.

A method of isolating sections of the channel layer in a SOI workpiece is disclosed. Rather than etching material to create trenches, which are then filled with a dielectric material, ions are implanted into portions of the channel layer to transform these implanted regions from silicon or silicon germanium into an electrically insulating material. These ions may comprise at least one isolating species, such as oxygen, nitrogen, carbon or boron. This eliminates various processes from the fabrication sequence, including an etching process and a deposition process. Advantageously, this approach also results in greater axial strain in the channel layer, since the channel layer is continuous across the workpiece.

An FDSOI device and fabrication method are disclosed. The device comprises: a buried oxide layer disposed on the silicon substrate; a SiGe channel disposed on the buried oxide layer, a nitrogen passivation layer disposed on the SiGe channel layer; a metal gate disposed on the nitrogen passivation layer, and sidewalls attached to sides of the metal gate; and a source and a drain regions disposed on the nitrogen passivation layer at both sides of the metal gate, wherein the source and drain regions are built in a raised SiGe layer. The stack structure of the SiGe layer and the nitrogen passivation layer forms the channel. This stack structure avoids the low stress of the silicon channel in the conventional device. In addition, it prevents the Ge diffusion from the SiGe channel to the gate dielectric in the conventional device. Thereby the invention improves reliability and performance of the device.

A semiconductor structure with an air gap includes a dielectric stack having a first dielectric layer on a substrate, a second dielectric layer on the first dielectric layer, and a third dielectric layer on the second dielectric layer. A first conductive layer and a second conductive layer are disposed in the dielectric stack. The first conductive layer and the second conductive layer are coplanar. A cross-like-shaped air gap is disposed in the dielectric stack between the first and second conductive layers. An oxide layer is disposed on a sidewall of the second dielectric layer within the cross-like-shaped air gap.

Structures including electrical isolation and methods of forming a structure including electrical isolation. A semiconductor layer is formed over a semiconductor substrate and shallow trench isolation regions are formed in the semiconductor layer. The semiconductor layer includes single-crystal semiconductor material having an electrical resistivity that is greater than or equal to 1000 ohm-cm. The shallow trench isolation regions are arranged to surround a portion of the semiconductor layer to define an active device region. A polycrystalline layer is positioned in the semiconductor layer and extends laterally beneath the active device region and the shallow trench isolation regions that surround the active device region.

An isolator includes a first insulating portion, a first electrode provided in the first insulating portion, a second insulating portion provided on the first insulating portion and the first electrode, a third insulating portion provided on the second insulating portion, and a second electrode provided in the third insulating portion. The second insulating portion includes a plurality of first voids and a second void. The plurality of first voids are arranged in a first direction parallel to an interface between the first insulating portion and the second insulating portion. At least one of the first voids is provided under the second void.