Abstract: The invention relates to a method of producing a stacked structure. The inventive method comprises the following steps consisting in: a) using a first plate (1) which is, for example, made from silicon, and a second plate (5) which is also, for example, made from silicon, such that at least one of said first (1) and second (5) plates has, at least in part, a surface (2; 7) that cannot bond to the other plate; b) providing a surface layer (3; 8), which is, for example, made from silicon oxide, on at least one part of the surface (2) of the first plate and/or the surface (7) of the second plate (5); and c) bonding the two plates (1; 5) to one another. The aforementioned bonding incompatibility can, for example, result from the physicochemical nature of the surface or of a coating applied thereto, or from a roughness value (r?2, r?7) which is greater than a predetermined threshold. The invention also relates to a stacked structure produced using the inventive method.

Abstract: A method for determining a minimum tension compensation stress which will have a membrane of a thickness of less than or equal to one micrometer, secured to a frame, having, in the absence of any external stress, a desired deflection. The membrane can be made as planar as possible in absence of any external stress, and its thickness can be less than or equal to one micrometer.

Abstract: The invention relates to a process for producing a bond between a first and a second substrate. The process includes preparing surfaces of the substrates to be assembled, and attaching the surfaces to form an assembly of these two surfaces, by direct molecular bonding. The assembly is then heat treated, which includes maintaining the temperature within the range of 50° C. to 100° C. for at least one hour.

Abstract: A method of transferring a layer of a first material onto a second substrate of a second material includes, a step of forming a first embrittlement plane in a first substrate in first material, by a first ion and/or atom implantation through a first face of said substrate, a step of forming a second embrittlement plane in said first substrate, by a first ion and/or atom implantation through a second face of said substrate, in order to reduce a curvature of this first substrate, a step of assembling the first and second substrates, and a step of separating a layer from the first substrate at the level of the first embrittlement plane, without separation at the level of the second embrittlement plane.

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: Two plates, each comprising a thin layer of silicon or silicon oxide at a surface thereof, are bonded by subjecting the thin layer of at least one of the plates to a surface treatment step forming a silicon oxynitride superficial thin film with a thickness of less than 5 nm. The thin film is performed with a nitrogen-based plasma generated by an inductively coupled plasma source. Furthermore, a potential difference applied between the plasma and a substrate holder supporting said plate during the surface treatment step is less than 50 V, advantageously less than 15 V and preferably zero. This enables a defect-free bonding interface to be obtained irrespective of a temperature of any heat treatment carried out after a contacting step between the respective thin layers of the two plates.

Abstract: A method of fabricating a mixed microtechnology structure includes providing a provisional substrate including a sacrificial layer on which is formed a mixed layer including at least first patterns of a first material and second patterns of a second material different from the first material, where the first and second patterns reside adjacent the sacrificial layer. The sacrificial layer is removed exposing a mixed surface of the mixed layer, the mixed surface including portions of the first patterns and portions of the second patterns. A continuous is formed covering layer of a third material on the mixed surface by direct bonding.

Abstract: The invention generally pertains to the field of solid immersion lenses for optical applications in high resolution microscopy. The lens of the invention includes a spherical sector limited by a planar surface and an object having nanometric dimensions arranged on the planar surface at the focus of said solid immersion lens. A light-opaque layer having a central opening with nanometric dimensions can be provided on the planar surface, said opening being centred on the focus of the solid immersion lens. The nano-object can be a tube or a thread having a cylindrical shape. The lens of the invention can be made using lithography techniques.

Abstract: A process for transferring a thin film includes forming a layer of inclusions to create traps for gaseous compounds. The inclusions can be in the form of one or more implanted regions that function as confinement layers configured to trap implanted species. Further, the inclusions can be in the form of one or more layers deposited by a chemical vapor deposition, epitaxial growth, ion sputtering, or a stressed region or layer formed by any of the aforementioned processes. The inclusions can also be a region formed by heat treatment of an initial support or by heat treatment of a layer formed by any of the aforementioned processes, or by etching cavities in a layer. In a subsequent step, gaseous compounds are introduced into the layer of inclusions to form micro-cavities that form a fracture plane along which the thin film can be separated from a remainder of the substrate.

Abstract: An assembly method to enable local electrical bonds between zones located on a face of a first substrate and corresponding zones located on a face of a second substrate, the faces being located facing each other, at least one of the substrates having a surface topography. The method forms an intermediate layer including at least one burial layer on the face of the substrate or substrates having a surface topography to make it (them) compatible with molecular bonding of the faces of substrates to each other from a topographic point of view, resistivity and/or thickness of the intermediate layer being chosen to enable the local electrical bonds, brings the two faces into contact, the substrates positioned to create electrical bonds between areas on the first substrate and corresponding areas on the second substrate, and bonds the faces by molecular bonding.

Abstract: The invention relates to a method for production of a detachable substrate, comprising a method step for the production of an interface by means of fixing, using molecular adhesion, one face of a layer on one face of a substrate, in which, before fixing, a treatment stage for at least one of said faces is provided, rendering the mechanical hold at the interface at such a controlled level to be compatible with a subsequent detachment.

Abstract: A process for transferring a thin film includes forming a layer of inclusions to create traps for gaseous compounds. The inclusions can be in the form of one or more implanted regions that function as confinement layers configured to trap implanted species. Further, the inclusions can be in the form of one or more layers deposited by a chemical vapor deposition, epitaxial growth, ion sputtering, or a stressed region or layer formed by any of the aforementioned processes. The inclusions can also be a region formed by heat treatment of an initial support or by heat treatment of a layer formed by any of the aforementioned processes, or by etching cavities in a layer. In a subsequent step, gaseous compounds are introduced into the layer of inclusions to form micro-cavities that form a fracture plane along which the thin film can be separated from a remainder of the substrate.

Abstract: A microstructure of the semiconductor on insulator type with different patterns is produced by forming a stacked uniform structure including a plate forming a substrate, a continuous insulative layer and a semiconductor layer. The continuous insulative layer is a stack of at least three elementary layers, including a bottom elementary layer, at least one intermediate elementary layer, and a top elementary layer overlying the semiconductor layer, where at least one of the bottom elementary layer and the top elementary layer being of an insulative material. In the stacked uniform structure, at least two patterns are differentiated by modifying at least one of the elementary layers in one of the patterns so that the elementary layer has a significantly different physical or chemical property between the two patterns, where at least one of the bottom and top elementary layer is an insulative material that remains unchanged.

Abstract: The invention relates to a method for producing a semiconducting structure including: controlled formation, through a mask (31), in a first substrate (30) in a semiconducting material, of at least one first area in an insulating material (36), up to the level of the lower surface (35) of the mask, before or during the removal of the mask.

Abstract: The invention relates to a process for obtaining a thin layer made of a first material on a substrate made of a second material called the final substrate, including the following steps: bonding a thick layer of a first material on one of its main faces on the final substrate at an interface, implantation of gaseous species in the thick layer of first material to create a weakened zone delimiting said thin layer between the interface and the weakened zone, deposit a layer of third material called the self-supporting layer on the thick layer made of first material, fracture within the structure composed of the final substrate, the thick layer of first material and the layer of third material, at the weakened zone to supply the substrate supporting said thin layer.

Abstract: A method for fabricating semiconductor on insulator wafers by providing a semiconductor substrate or a substrate that includes an epitaxial semiconductor layer as a source substrate, attaching the source substrate to a handle substrate to form a source handle assembly and detaching the source substrate at a predetermined splitting area provided inside the source substrate and being essentially parallel to its main surface, to remove a layer from the source handle assembly to thereby create the semiconductor on insulator wafer. A diffusion barrier layer, in particular, an oxygen diffusion barrier layer can be provided on the source substrate. In addition the invention relates to the corresponding semiconductor on insulator wafers that are produced by the method.

Abstract: The invention generally pertains to the field of solid immersion lenses for optical applications in high resolution microscopy. The lens of the invention includes a spherical sector limited by a planar surface and an object having nanometric dimensions arranged on the planar surface at the focus of said solid immersion lens. A light-opaque layer having a central opening with nanometric dimensions can be provided on the planar surface, said opening being centred on the focus of the solid immersion lens. The nano-object can be a tube or a thread having a cylindrical shape. The lens of the invention can be made using lithography techniques.

Abstract: A method of making a complex microelectronic structure by assembling two substrates through two respective linking surfaces, the structure being designed to be dissociated at a separation zone. Prior to assembly, in producing a state difference in the tangential stresses between the two surfaces to be assembled, the state difference is selected so as to produce in the assembled structure a predetermined stress state at the time of dissociation.

Abstract: The invention relates to the preparation of a thin layer comprising a step in which an interface is created between a layer used to create said thin layer and a substrate, characterized in that said interface is made in such a way that it is provided with at least one first zone (Z1) which has a first level of mechanical strength, and a second zone (Z2) which has a level of mechanical strength which is substantially lower than that of the first zone. Said interface can be created by glueing surfaces which are prepared in a differentiated manner, by a layer which is buried and embrittled in a differentiated manner in said zones, or by an intermediate porous layer.

Abstract: The invention concerns a method of producing a mixed substrate, that is to say a substrate comprising at least one block of material different from the material of the substrate, the method comprising the following successive steps: formation of a cavity in a substrate of first material, and from one of its faces, the formation of the cavity being carried out so as to leave at least part of the first material projecting from the bottom of the cavity, formation of the block by means of a reaction, initiated from the walls of the cavity, between the first material and at least one chemical element contributed in order to obtain a second material filling the cavity, the formation of the block being carried out so as to obtain, from the part of the first material projecting, a protrusion of second material projecting on said face of the substrate.