Abstract: A manufacturing method including supplying a first substrate including a first face designated front face, the front face being made of a III-V type semiconductor, supplying a second substrate, forming a radical oxide layer on the front face of the first substrate by executing a radical oxidation, assembling, by a step of direct bonding, the first substrate and the second substrate so as to form an assembly including the radical oxide layer intercalated between the first and second substrates, executing a heat treatment intended to reinforce the assembly interface, and making disappear, at least partially, the radical oxide layer.

Abstract: A method for thinning samples including the steps of: a) providing at least one sample having a front and a rear face, b) providing a frame substrate having a first face and a second face opposite the first, including a through-opening which opens into the first and second face, which is configured to receive the sample, c) positioning the sample so it is disposed in the through-opening, the front face being oriented to the same side as the first face, and d) thinning the frame substrate and the sample simultaneously from the first face and the front face, respectively, so that at the end of thinning, the faces extend substantially in the same plane, the thinning being carried out using a grinder, the frame substrate and the sample being disposed on a rotary disk held in place by aspiration, the flanks of the sample remaining free during the thinning.

Abstract: A method for producing a structure by direct bonding of two elements, the method including: production of the elements to be assembled and assembly of the elements. The production of the elements to be assembled includes: deposition on a substrate of a TiN layer by physical vapor deposition, and deposition of a copper layer on the TiN layer. The assembly of the elements includes: polishing the surfaces of the copper layers intended to come into contact so that they have a roughness of less than 1 nm RMS and hydrophilic properties, bringing the surfaces into contact, and storing the structure at atmospheric pressure and at ambient temperature.

Abstract: A method for manufacturing a flexible structure including implanting ionic species in first and second source substrates so as to form first and second embrittlement regions respectively, delimiting first and second thin films, providing a flexible substrate, the stiffness R of which is less than or equal to 107 GPa·?m3, securing the first and second thin films to the first and second faces of the flexible substrate respectively so as to form a stack including the flexible structure delimited by the first and second embrittlement regions, the flexible structure having a stiffening effect suitable for allowing transfers of the first and second thin films, and applying a thermal budget so as to transfer the first and second thin films onto the flexible substrate.

Abstract: A method for obtaining a film made out of a first material on a polymer support, said method comprising bonding a first wafer to a second wafer, thereby defining a bonding interface between said first wafer and said second wafer, at least one of said first and second wafers comprising a layer of said first material situated in proximity to said bonding interface, in said first wafer, hollowing out a cavity, said cavity comprising a bottom parallel to said bonding interface that defines, in said first wafer, a bottom zone at a controlled distance relative to said second wafer, forming, in said cavity, a polymer layer on a thickness controlled from a bottom thereof to obtain a combined wafer portion, said combined wafer portion comprising a bottom zone formed by said polymer layer on said bottom and a peripheral zone, and eliminating said second wafer on a major portion of a thickness thereof, thereby releasing, beneath said polymer layer, a film comprising said layer of said first material.

Abstract: A method for treating at least one first material layer including siloxane bonds, wherein at least one surface can be interlocked with a surface of a second material layer by direct bonding, the method including: at least one forced diffusion at a temperature greater than or equal to 30° C., at least in the first material layer, of chemical species including at least one pair of free electrons and at least one labile proton; and converting at least one portion of the siloxane bonds into silanol bonds in at least one portion of the first material layer extending from the surface to a depth greater than or equal to approximately 10 nm.

Abstract: The process wherein steps consisting in: a) implanting ionic species through a substrate with at least on its surface, a crystalline layer of SixGe1-x, so as to form a weakened plane in said layer, bounding a seed film; b) depositing an amorphous layer of SiyGe1-y on the seed film; c) applying a splitting process so as to obtain a detached structure comprising the seed film and the amorphous SiyGe1-y layer on the one hand, and a negative of the substrate on the other hand; and d) applying, to the detached structure, a heat treatment so as to obtain a thick crystalline layer with a thickness larger than 10 microns, which layer is not secured to the negative. The invention also relates to a structure wherein a crystalline silicon substrate wherein a seed film and amorphous silicon layer containing a stressed region comprising implanted ions.

Abstract: A method for treating at least one first material layer including siloxane bonds, wherein at least one surface can be interlocked with a surface of a second material layer by direct bonding, the method including: at least one forced diffusion at a temperature greater than or equal to 30° C., at least in the first material layer, of chemical species including at least one pair of free electrons and at least one labile proton; and converting at least one portion of the siloxane bonds into silanol bonds in at least one portion of the first material layer extending from the surface to a depth greater than or equal to approximately 10 nm.

Abstract: A method of transferring a layer including: a) providing a layer joined to an initial substrate with a binding energy E0; b) bonding a front face of the layer on an intermediate substrate according to an intermediate bonding energy Ei; c) detaching the initial substrate from the layer; e) bonding a rear face onto a final substrate according to a final bonding energy Ef; and f) debonding the intermediate substrate from the layer to transfer the layer onto the final substrate; step b) comprising a step of forming siloxane bonds Si—O—Si, step c) being carried out in a first anhydrous atmosphere and step f) being carried out in a second wet atmosphere such that the intermediate bonding energy Ei takes a first value Ei1 in step c) and a second value Ei2 in step f), with Ei1>E0 and Ei2<Ef.

Abstract: A method for producing a microelectronic device provided with different strained areas in the superficial layer of a semi-conductor on insulator type substrate comprising amorphizing a region of said superficial layer and then a lateral recrystallization of said region from crystalline areas adjoining this region (FIG. 1E).

Abstract: A method of sealing a first wafer and a second wafer each made of semiconducting materials, including: implanting a metallic species in at least the first wafer, assembling the first wafer and the second wafer by molecular bonding, and after the molecular bonding, forming a metallic ohmic contact including alloys formed between the implanted metallic species and the semiconducting materials of the first wafer and the second wafer, the metallic ohmic contact being formed at an assembly interface between the first wafer and the second wafer, wherein the forming includes causing the implanted metallic species to diffuse towards the interface between the first wafer with the second wafer and beyond the interface.

Abstract: A method for transferring a thin layer of monocrystalline silicon from a free face of a monocrystalline silicon donor substrate having a thickness greater than that of the thin layer includes implanting ions through the free face to form a buried brittle layer in the silicon, using a polymer layer, bonding the donor substrate, by the free face, to a receiver substrate, and fracturing the thin layer from the donor substrate at the buried brittle layer by thermal fracture processing, and selecting conditions of implantation such that a thickness of the thin layer is smaller than 10 micrometers, and a thickness of the polymer layer is below a critical threshold defined as a function of energy and dose of the implantation, the critical threshold being less than or equal to the lesser of 500 nanometers and the thin layer's thickness.

Abstract: A method for producing of at least one photovoltaic cell includes successively the anisotropic etching of a surface of a crystalline silicon substrate and the isotropic etching treatment of said surface. The isotropic etching treatment includes at least two successive operations respectively consisting in forming a silicon oxide thin film with a controlled average thickness, ranging between 10 nm and 500 nm and in removing said thin film thus-formed. The operation consisting in forming a silicon oxide thin film on the face of the substrate is carried out by a thermally activated dry oxidation. Such a method makes it possible to improve the surface quality of the surface of the substrate once said surface is etched in an anisotropic way.

Abstract: A method for producing a hybrid substrate, including a support substrate, a continuous buried insulator layer and, on this continuous layer, a hybrid layer including alternating zones of a first material and at least one second material, wherein these two materials are different by their nature and/or their crystallographic characteristics. The method forms a hybrid layer, including alternating zones of first and second materials, on a homogeneous substrate, assembles this hybrid layer, the continuous insulator layer and the support substrate, and eliminates a part at least of the homogeneous substrate, before or after the assembling.

Abstract: A method of transferring a layer including: a) providing a layer joined to an initial substrate with a binding energy E0; b) bonding a front face of the layer on an intermediate substrate according to an intermediate bonding energy Ei; c) detaching the initial substrate from the layer; e) bonding a rear face onto a final substrate according to a final bonding energy Ef; and f) debonding the intermediate substrate from the layer to transfer the layer onto the final substrate; step b) comprising a step of forming siloxane bonds Si—O—Si, step c) being carried out in a first anhydrous atmosphere and step f) being carried out in a second wet atmosphere such that the intermediate bonding energy Ei takes a first value Ei1 in step c) and a second value Ei2 in step f), with Ei1>E0 and Ei2<Ef.

Abstract: A method for performing at least one mechanical operation on a structure including at least one first layer stacked onto at least a second layer, the first layer including at least one material with a Young's modulus equal to or higher than about 50 GPa and higher than that of at least one material of the second layer, the method including: thinning the first layer, located at least at one area of the structure intended to undergo application of a pressing force upon implementing the mechanical operation; and implementing the mechanical operation including applying the pressing force located on at least one part of the area of the structure.

Abstract: A method for recycling a substrate holder adapted to receive a substrate for at least one deposition step of a layer of a material on the substrate also leading to the depositing of a layer of a material on the substrate holder, the method including implanting ion species through a receiving surface of the substrate holder so as to form at least one buried weakened plane delimiting a thin film underneath the receiving surface of the substrate holder, exfoliating the thin film from the substrate holder so as to break up the thin film, and removing a stack including at least one layer of a material deposited on the thin film resulting from the at least one deposition step of the layer of a material on the substrate.

Abstract: A process for fabricating an acoustic wave resonator comprising a suspended membrane comprising a piezoelectric material layer, comprises the following steps: production of a first stack comprising at least one layer of first piezoelectric material on the surface of a first substrate; production of a second stack comprising at least one second substrate; production of at least one non-bonding initiating zone by deposition or creation of particles of controlled sizes leaving the surface of one of said stacks endowed locally with projecting nanostructures before a subsequent bonding step; direct bonding of said two stacks creating a blister between the stacks, due to the presence of the non-bonding initiating zone; and, thinning of the first stack to eliminate at least the first substrate.

Abstract: A process for manufacturing a stacked structure comprising at least one thin layer bonded to a target substrate, in which a thin layer is formed by introduction gaseous species into an initial substrate, to form a weakened layer separating a film from the rest of the initial substrate, a first contact face of the thin layer is bonded to a face of an intermediate substrate by molecular adhesion, and the initial substrate is fractured at the weakened layer so as to expose a free face of the thin layer. The intermediate substrate is then removed in order to obtain the stacked structure.

Abstract: A method for trimming a structure obtained by bonding a first wafer to a second waver on contact faces and thinning the first waver, wherein at least either the first wafer or the second wafer is chamfered and thus exposes the edge of the contact face of the first wafer, wherein the trimming concerns the first wafer. The method includes a) selecting the second wafer from among wafers with a resistance to a chemical etching planned in b) that is sufficient with respect to the first wafer to allow b) to be carried out; b) after bonding the first wafer to the second wafer, chemical etching the edge of the first wafer to form in the first wafer a pedestal resting entirely on the contact face of the second wafer and supporting the remaining of the first wafer; and c) thinning the first wafer until the pedestal is reached and attacked, to provide a thinned part of the first wafer.