A wafer has a layer containing silicon, a layer of polycrystalline diamond deposited on the silicon-containing layer, and a bow-compensation layer on the other side of the silicon-containing layer for reducing wafer-bow. A method of making a bonded structure includes an activation process for creating dangling bonds on the surface of one substrate, followed by contact-bonding the surface to a second substrate at low temperature. A bonded structure may include two substrates contact bonded to each other, one substrate including a layer containing silicon, a layer of polycrystalline diamond, a bow-compensation layer for reducing wafer-bow of the first substrate, and the other substrate including gallium nitride, silicon carbide, lithium niobate, lithium tantalate, gallium arsenide, indium phosphide, or another suitable material other than diamond.

A method includes having a first wafer bonding recipe and a model of a wafer bonding process, the model comprising an input indicative of a physical parameter of a first wafer to be bonded to a second wafer and configured to output a wafer bonding recipe based on the physical parameter of the first wafer; obtaining measurements of the first wafer to obtain the physical parameter of the first wafer; generating, by the model, the first wafer bonding recipe based on the physical parameter of the first wafer; and bonding the first wafer to the second wafer in accordance with the first wafer bonding recipe to produce a first post-bond wafer.

A method for manufacturing a semiconductor device includes the steps of a first separation process of separating the semiconductor layer from the first substrate by bringing a pick-up substrate into close contact with the semiconductor layer and then moving the pick-up substrate away from the first substrate, pressing of pressing the semiconductor layer that is in close contact with the pick-up substrate to the second substrate, temperature maintenance of maintaining temperatures of contact surfaces of the semiconductor layer and the second substrate at a temperature higher than room temperature while pressing the semiconductor layer onto the second substrate, and a second separation process of separating the semiconductor layer from the pick-up substrate after the temperatures of the contact surfaces are maintained at the temperature higher than room temperature.

The invention relates to a measuring device for determining a course of a bonding wave in a gap (3) between a first substrate (2) and a second substrate (4).

Furthermore, the present invention relates to a corresponding method.

A process for forming a predetermined separation zone inside a donor substrate, in particular, to be used in a process of transferring a layer onto a carrier substrate comprises an implantation step that is carried out such that the implantation dose in a zone of the edge of the donor substrate is lower than the implantation dose in a central zone of the donor substrate to limit the formation of particles during thermal annealing. The present disclosure also relates to a donor substrate for a process of transferring a thin layer onto a carrier substrate produced by means of the process described above. The present disclosure also relates to a device for limiting an implantation region to a zone of the edge of a donor substrate.

A method of forming an insulation structure inside and on top of a first semiconductor substrate, including the steps of: a) forming a trench vertically extending in the first substrate from a first surface of the first substrate; b) filling the trench, from the first surface of the first substrate, with a polysilicon region; c) thinning the first substrate on the side of a second surface of the first substrate, opposite to the first surface, to expose the polysilicon region at the bottom of the trench; d) removing the polysilicon region from the second surface of the first substrate; and e) filling the trench, from the second surface of the first substrate, with a metal.

A method includes having a first wafer bonding recipe and a model of a wafer bonding process, the model comprising an input indicative of a physical parameter of a first wafer to be bonded to a second wafer and configured to output a wafer bonding recipe based on the physical parameter of the first wafer; obtaining measurements of the first wafer to obtain the physical parameter of the first wafer; generating, by the model, the first wafer bonding recipe based on the physical parameter of the first wafer; and bonding the first wafer to the second wafer in accordance with the first wafer bonding recipe to produce a first post-bond wafer.

Techniques herein include methods for fabricating high density logic and memory for advanced circuit architecture. The methods can include forming multilayer stacks on separate substrates and forming bonding films over the multilayer stacks, then contacting and bonding the bonding films to form a combined structure including each of the multilayer stacks. The method can be repeated to form additional combinations. In between iterations, transistor devices may be formed from the combined structures. Ionized atom implantation can facilitate cleavage of a substrate destined for growth of additional multilayers, wherein an anneal weakens the substrate at a predetermined penetration depth of the ionized atom implantation.

A method for transferring a superficial layer from a detachable structure comprises the following steps: a) supplying the detachable structure comprising: •a support substrate, •a detachable layer arranged on the support substrate along a main plane and comprising a plurality of walls that are separated from one another, each wall having at least one side that is perpendicular to the main plane; •a superficial layer arranged on the detachable layer along the main plane; b) applying a mechanical force configured to cause said walls to bend, along a direction that is secant to said side, until causing the mechanical rupture of the walls, in order to detach the superficial layer from the support substrate.

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.