A glass substrate has a compaction of 0.1 to 100 ppm. An absolute value |Δα.sub.50/100| of a difference between an average coefficient of thermal expansion α.sub.50/100 of the glass substrate and an average coefficient of thermal expansion of single-crystal silicon at 50° C. to 100° C., an absolute value |Δα.sub.100/200| of a difference between an average coefficient of thermal expansion α.sub.100/200 of the glass substrate and an average coefficient of thermal expansion of the single-crystal silicon at 100° C. to 200° C., and an absolute value |Δα.sub.200/300| of a difference between an average coefficient of thermal expansion α.sub.200/300 of the glass substrate and an average coefficient of thermal expansion of the single-crystal silicon at 200° C. to 300° C. are 0.16 ppm/° C. or less.

Assemblies including a device layer of a silicon-on-insulator (SOI) substrate and a replacement substrate replacing a handle wafer of the SOI substrate, and methods for transferring the device layer of the SOI substrate from the handle wafer to the replacement substrate. A device structure is formed in a first section of the handle wafer, and a second section of the handle wafer adjoining the first section of the handle wafer is removed to expose a surface of the buried dielectric layer of the silicon-on-insulator substrate. A permanent substrate is attached to the surface of the buried dielectric layer. When the permanent substrate is attached to the surface of the buried dielectric layer, the section of the handle wafer is received inside a cavity defined in the permanent substrate.

A semiconductor-on-insulator substrate for use in RF applications, such as a silicon-on-insulator substrate, comprises a semiconductor top layer, a buried oxide layer and a passivation layer over a support substrate. In addition, a penetration layer is provided between the passivation layer and the silicon support substrate to ensure sufficient high resistivity below RF features and avoid increased migration of dislocations in the support substrate. RE devices may be fabricated on and/or in such a semiconductor-on-insulator substrate.

A method for manufacturing a semiconductor-on-insulator substrate by BESOI comprising the following steps: a) provide a structure comprising a first substrate, a first stopping layer made of SiGe having an atomic percentage of Ge lower than or equal to 30%, an intermediate layer, a second stopping layer made of SiGe having a thickness smaller than the thickness of the first stopping layer and an atomic percentage of Ge higher than or equal to 20%, optionally an active area formed by a layer made of silicon or by a stack of active layers made of Si and SiGe, a dielectric layer, a second substrate, b) thin and then etch the first substrate made of silicon, from the first main face up to the second main face, c) successively remove the first stopping layer, the intermediate layer, and optionally the second stopping layer to obtain a SOI or SiGeOI substrate.

The present disclosure, in some embodiments, relates to a method of forming a semiconductor structure. The method includes forming a plurality of bulk micro defects within a handle substrate. Sizes of the plurality of bulk micro defects are increased to form a plurality of bulk macro defects (BMDs) within the handle substrate. Some of the plurality of BMDs are removed from within a first denuded region and a second denuded region arranged along opposing surfaces of the handle substrate. An insulating layer is formed onto the handle substrate. A device layer comprising a semiconductor material is formed onto the insulating layer. The first denuded region and the second denuded region vertically surround a central region of the handle substrate that has a higher concentration of the plurality of BMDs than both the first denuded region and the second denuded region.

A semiconductor device and a method of fabricating the semiconductor device are disclosed. The method includes: providing a device wafer and a carrier wafer, the device wafer including an SOI substrate comprising, stacked from the bottom upward, a lower substrate, a buried insulator layer and a semiconductor layer; bonding the device wafer at a front side thereof to the carrier wafer; removing at least the lower substrate through thinning the device wafer from a backside thereof, wherein the backside of the device wafer opposes the front side thereof; and providing a high-resistance substrate and bonding the device wafer at the backside thereof to the high-resistance substrate, the high-resistance substrate having a resistivity higher than that of the lower substrate. With the present disclosure, lower signal loss and improved signal linearity can be achieved while avoiding a significant cost increase.

Provided are a semiconductor structure and a manufacturing method thereof. The semiconductor structure includes a carrier substrate, a trap-rich layer, a dielectric layer, an interconnect structure, a device structure layer and a circuit structure. The trap-rich layer is disposed on the carrier substrate. The dielectric layer is disposed on the trap-rich layer. The interconnect structure is disposed on the dielectric layer. The device structure layer is disposed on the interconnect structure and electrically connected to the interconnect structure. The circuit structure is disposed on the device structure layer and electrically connected to the device structure layer.

A composite substrate is provided in some embodiments of the present disclosure, which includes a substrate, an insulation layer, a first silicon-containing layer and a first epitaxial layer. The insulation layer is disposed on the substrate. The first silicon-containing layer is disposed on the insulation layer, in which the first silicon-containing layer includes a plurality of group V atoms. The first epitaxial layer is disposed on the first silicon-containing layer, in which the first epitaxial layer includes a plurality of group III atoms. A distribution concentration of the group V atoms in the first silicon-containing layer increases as getting closer to the first epitaxial layer, and a distribution concentration of the group III atoms in the first epitaxial layer increases as getting closer to the first silicon-containing layer. A method of manufacturing a composite substrate is also provided in some embodiments of the present disclosure.

A layer transfer process comprises depositing a first, temporary bonding layer of SOG comprising methylsiloxane by spin coating on a surface comprising substantially no silicon of an initial substrate, and applying a first heat treatment for densifying the first, temporary bonding layer. An intermediate substrate is joined to the initial substrate, and then thinned A second bonding layer of SOG comprising silicate or methylsilsesquioxane is deposited by spin coating on a surface of the thinned initial substrate and/or a final substrate, and a second heat treatment is applied for densifying the second bonding layer. The thinned initial substrate and the final substrate and then joined, and the intermediate substrate is detached thereafter. The process may be carried out at temperatures below 300° C. to avoid damaging components that may be present in the substrates.

A semiconductor device is provided, which includes a multi-layered substrate having an interposed polymeric film and a device layer arranged over the multi-layered substrate.