A method and a corresponding device for bonding a first substrate with a second substrate at mutually facing contact faces of the substrates. The method includes holding of the first substrate to a first holding surface of a first holding device and holding of the second substrate to a second holding surface of a second holding device. A change in curvature of the contact face of the first substrate and/or a change in curvature of the contact face of the second substrate are controlled during the bonding.

A method for producing a multilayer structure includes the following steps: a) providing a first substrate, b) depositing a thick layer of a precursor formulation including a preceramic polymer filled with inorganic particles on the first substrate, c) providing a second substrate, d) adhesively bonding the thick layer and the second substrate, e) thinning the first substrate or the second substrate so as to obtain an active layer, f) applying a pyrolysis heat treatment so as to ceramize the preceramic polymer of the thick layer and to obtain a ceramic matrix composite material, the filler content and the nature of the inorganic particles being chosen so that the thick layer has a coefficient of thermal expansion which differs, at most, by 15% from that of the first substrate and from that of the second substrate.

Methods for improving wafer bonding performance are disclosed herein. In some embodiments, a method for bonding a pair of semiconductor substrates is disclosed. The method includes: processing at least one of the pair of semiconductor substrates, and bonding the pair of semiconductor substrates together. Each of the pair of semiconductor substrates is processed by: performing at least one chemical vapor deposition (CVD), and performing at least one chemical mechanical polishing (CMP). One of the at least one CVD is performed after all CMP performed before bonding.

A method for producing a laminate of two silicon substrates, which includes: (a) providing a first silicon substrate having a first bonding part and a second silicon substrate having a second bonding part, wherein the first bonding part and the second bonding part are portions containing a silicon oxide; and bonding the first bonding part and the second bonding part with a reaction product derived from an organic material reactive with a hydrosilyl group and/or a silanol group. Also disclosed is a laminate including the two silicon substrates.

Discontinuous bonds for semiconductor devices are disclosed herein. A device in accordance with a particular embodiment includes a first substrate and a second substrate, with at least one of the first substrate and the second substrate having a plurality of solid-state transducers. The second substrate can include a plurality of projections and a plurality of intermediate regions and can be bonded to the first substrate with a discontinuous bond. Individual solid-state transducers can be disposed at least partially within corresponding intermediate regions and the discontinuous bond can include bonding material bonding the individual solid-state transducers to blind ends of corresponding intermediate regions. Associated methods and systems of discontinuous bonds for semiconductor devices are disclosed herein.

Method for reversible bonding between a first element and a second element, comprising the implementation of the following steps: a) producing at least one oxide layer on at least one first face of the first element or of the second element; b) joining the first face of the first element with the first face of the second element such that the oxide layer forms a bonding interface between the first element and the second element; c) disjoining the second element with regard to the first element by the application of a heat treatment under controlled humid atmosphere physically and/or chemically degrading the oxide layer.

A method for manufacturing a semiconductor substrate according to the present invention includes preparing a seed substrate containing a semiconductor material, forming an ion implanted layer at a certain depth from a front surface of a main surface of the seed substrate by implanting ions into the seed substrate, growing a semiconductor layer on the main surface of the seed substrate with a vapor-phase synthesis method, and separating a semiconductor substrate including the semiconductor layer and a part of the seed substrate by irradiating the front surface of the main surface of at least any of the semiconductor layer and the seed substrate with light.

A method for producing a SiC composite substrate 10 having a single crystal SiC layer 12 on a polycrystalline SiC substrate 11. After the single crystal SiC layer 12 is provided on the front surface of a holding substrate 21 including Si and having a silicon oxide film 21a on the front and back surfaces thereof to produce a single crystal SiC layer supporting body 14, a part or all of the thickness of the silicon oxide film 21a on one area or all of the back surface of the holding substrate 21 in the single crystal SiC layer supporting body 14 is removed to impart warpage to the single crystal SiC layer supporting body 14. Then, polycrystalline SiC is deposited on the single crystal SiC layer 12 by chemical vapor deposition to form the polycrystalline SiC substrate 11, and the holding substrate is physically and/or chemically removed.

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.

A method and a device for bonding a first substrate with a second substrate inside a sealed bonding chamber. The method includes: a) fixing of the first and second substrates, b) arranging of the first and second substrates, c) mutual approaching of the first and second substrates, d) contacting the first and second substrates at respective bond initiation points, e) generating a bonding wave running from the bond initiation points to side edges of the substrates, and f) influencing the bonding wave during course of the bonding wave, wherein targeted influencing of the bonding wave takes place by a regulated and/or controlled change of pressure inside the bonding chamber.