A process for collectively fabricating a plurality of semiconductor structures comprises providing a substrate including a carrier having a main face, a dielectric layer on the main face of the carrier and a plurality of crystalline semiconductor growth islands on the dielectric layer. At least one crystalline semiconductor active layer is formed on the growth islands. After the step of forming the active layer, trenches are formed in the active layer and in the growth islands in order to define the plurality of semiconductor structures.

A method for manufacturing a plurality of crystalline semiconductor islands having a variety of lattice parameters includes the following steps: providing a relaxation substrate that comprises a medium, a flow layer disposed on the medium and, a plurality of strained crystalline semiconductor islands having an initial lattice parameter located on the flow layer, a first group of islands having a first lattice parameter and a second group of islands having a second lattice parameter that is different from the first; and heat treating the relaxation substrate at a relaxation temperature greater than or equal to the glass transition temperature of the flow layer to cause differentiated lateral expansion of the islands of the first and second group. The lattice parameter of the relaxed islands of the first group and the relaxed islands of the second group then have different values.

A method and 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.

A method includes transferring a layer onto a flexible substrate, the layer being located in a stack on the front face of the substrate. The substrate includes at least one supplementary stack interposed between the stack and the bulk layer of the substrate. This supplementary stack includes at least two layers with thicknesses decreasing in the direction of the front face. The method makes provision, after bonding the flexible substrate on the front face, for successively and gradually removing the various layers of the substrate. Such gradualness makes it possible to transfer a thin layer of silicon, with a thickness of less than 50 nm, onto a flexible substrate.

A 3D semiconductor device, the device including: a first level including single crystal first transistors, and a first metal layer, where the first level is overlaid by a first isolation layer; a second level including second transistors, where the first isolation layer is overlaid by the second level, and where the second level is overlaid by a second isolation layer; a third level including single crystal third transistors, where the second isolation layer is overlaid by the third level, where the third level is overlaid by a third isolation layer, where the third level is bonded to the second isolation layer, where the bonded includes at least one oxide to oxide bond, and where the bonded includes at least one metal to metal bond.

A semiconductor structure includes a first wafer, a conductive via, an isolation layer, and a spacer structure. The first wafer includes a semiconductor substrate, a multi-level interconnect structure, and a dielectric layer. The semiconductor substrate has a front side and a back side. The multi-level interconnect structure is disposed over the front side of the semiconductor substrate. The dielectric layer is disposed over the back side of the semiconductor substrate. The conductive via extends from the dielectric layer to a conductive line of the multi-level interconnect structure. The isolation layer is disposed between the conductive via and the first wafer. The spacer structure is disposed between the conductive via and the isolation layer, in which the spacer structure is spaced apart from the conductive line.

A method of manufacturing an epitaxy substrate is provided. A handle substrate is provided. A beveling treatment is performed on an edge of a device substrate such that a bevel is formed at the edge of the device substrate, wherein a thickness of the device substrate is greater than 100 μm and less than 200 μm. An ion implantation process is performed on a first surface of the device substrate to form an implantation region within the first surface. A second surface of the device substrate is bonded to the handle substrate for forming the epitaxy substrate, wherein a bonding angle greater than 90° is provided between the bevel of the device substrate and the handle substrate, and a projection length of the bevel toward the handle substrate is between 600 μm and 800 μm.

A semiconductor device manufacturing method of an embodiment includes forming a first layer in a region of a first substrate excluding an outer peripheral portion thereof; forming a first semiconductor circuit above the first layer; for a second semiconductor circuit on a second substrate; forming a second layer with a predetermined width at an outer peripheral portion of the second substrate; bonding a surface of the first substrate on a side provided with the first semiconductor circuit and a surface of the second substrate on a side provided with the second semiconductor circuit; and applying tensile stress to the first layer and the second layer to debond the first layer and the second layer, thereby forming the second substrate including the first semiconductor circuit and the second semiconductor circuit.

A method for producing a 3D memory device, the method including: providing a first level including a single crystal layer and control circuits, where the control circuits include a plurality of first transistors; forming at least one second level above the first level; performing a first etch step including etching holes within the second level; performing additional processing steps to form a plurality of first memory cells within the second level, where each of the first memory cells include one of a plurality of second transistors, where the control circuits include memory peripheral circuits, where at least one of the first memory cells is at least partially atop a portion of the memory peripheral circuits, and where fabrication processing of the first transistors accounts for a temperature and time associated with the processing the second level and the plurality of second transistors by adjusting a process thermal budget of the first level accordingly.

Deformation of substrates after the substrates are bonded can be suppressed. A bonding apparatus includes a first holding unit configured to attract and hold a first substrate from above; a second holding unit provided under the first holding unit and configured to attract and hold a second substrate from below; and a striker configured to press a central portion of the first substrate from above and bring the first substrate into contact with the second substrate. The first holding unit is configured to attract and hold a partial region of a peripheral portion of the first substrate, and the first holding unit attracts and holds the region which intersects with a direction, among directions from the central portion of the first substrate toward the peripheral portion thereof, in which a bonding region between the first substrate and the second substrate is expanded faster.