Abstract: A substrate comprises a base wafer, an insulating layer over the base wafer, and a top semiconductor layer over the insulating layer on a side thereof opposite the base wafer. The insulating layer comprises a charge-confining layer confined on one or both sides with diffusion barrier layers, wherein the charge-confining layer has a density of charges in absolute value higher than 1010 charges/cm2. Alternatively, the insulating layer comprises charge-trapping islands embedded therein, wherein the charge-trapping islands have a total density of charges in absolute value higher than 1010 charges/cm2.

Abstract: Embodiments of the invention relate to substrates comprising a base wafer, an insulating layer and a top semiconductor layer, wherein the insulating layer comprises at least a zone wherein a density of charges is in absolute value higher than 1010 charges/cm2. The invention also relates to processes for making such substrates.

Abstract: Methods of bonding together semiconductor structures include annealing metal of a feature on a semiconductor structure prior to directly bonding the feature to a metal feature of another semiconductor structure to form a bonded metal structure, and annealing the bonded metal structure after the bonding process. The thermal budget of the first annealing process may be at least as high as a thermal budget of a later annealing process. Additional methods involve forming a void in a metal feature, and annealing the metal feature to expand the metal of the feature into the void. Bonded semiconductor structures and intermediate structures are formed using such methods.

Abstract: A process for avoiding formation of a Si—SiO2—H2 environment during a dissolution treatment of a semiconductor-on-insulator structure that includes a carrier substrate, an oxide layer, a thin layer of semiconductor material and a peripheral ring in which the oxide layer is exposed. This process includes encapsulating at least the exposed oxide layer of the peripheral ring with semiconductor material by performing a creep thermal treatment; and performing an oxide dissolution treatment to reduce part of the thickness of the oxide layer. In this process, the semiconductor material that encapsulates the oxide layer has a thickness before the oxide dissolution that is at least twice that of the oxide that is to be dissolved, thus avoiding formation of a Si—SiO2—H2 environment on the peripheral ring where the oxide layer would otherwise be exposed.

Abstract: Embodiments of the invention relate to substrates comprising a base wafer, an insulating layer and a top semiconductor layer, wherein the insulating layer comprises at least a zone wherein a density of charges is in absolute value higher than 1010 charges/cm2. The invention also relates to processes for making such substrates.

Abstract: A method for producing a structure having an ultra thin buried oxide (UTBOX) layer by assembling a donor substrate with a receiver substrate wherein at least one of the substrates includes an insulating layer having a thickness of less than 50 nm that faces the other substrate, conducting a first heat treatment for reinforcing the assembly between the two substrates at temperature below 400° C., and conducting a second heat treatment at temperature above 900° C., wherein the exposure time between 400° C. and 900° C. between the heat treatments is less than 1 minute and advantageously less than 30 seconds.

Abstract: A method of producing a layer of cavities in a structure comprises at least one substrate formed from a material that can be oxidized or nitrided, the method comprising the following steps: implanting ions into the substrate in order to form an implanted ion concentration zone at a predetermined mean depth; heat treating the implanted substrate to form a layer of cavities at the implanted ion concentration zone; and forming an insulating layer in the substrate by thermochemical treatment from one surface of the substrate, the insulating layer that is formed extending at least partially into the layer of cavities.

Abstract: The invention relates to an electronic device for radio frequency or power applications, comprising a semiconductor layer supporting electronic components on a support substrate, wherein the support substrate comprises a base layer having a thermal conductivity of at least 30 W/m K and a superficial layer having a thickness of at least 5 ?m, the superficial layer having an electrical resistivity of at least 3000 Ohm·cm and a thermal conductivity of at least 30 W/m K. The invention also relates to two processes for manufacturing such a device.

Abstract: Embodiments of the invention relate to substrates comprising a base wafer, an insulating layer and a top semiconductor layer, wherein the insulating layer comprises at least a zone wherein a density of charges is in absolute value higher than 1010 charges/cm2. The invention also relates to processes for making such substrates.

Abstract: A method for producing a stacked structure having an ultra thin buried oxide (UTBOX) layer therein by forming an electrical insulator layer on a donor substrate, introducing elements into the donor substrate through the insulator layer, forming an electrical insulator layer, on a second substrate, and bonding the two substrates together to form the stack, with the two insulator layers limiting the diffusion of water and forming the UTBOX layer between the two substrates at a thickness of less than 50 nm, wherein the donor oxide layer has, during bonding, a thickness at least equal to that of the bonding oxide layer.

Abstract: A method for manufacturing components on a mixed substrate. The method comprises the following steps: providing a substrate of the semiconductor-on-insulator (SeOI) type comprising a buried oxide layer between a supporting substrate and a thin layer, forming in this substrate a plurality of trenches opening out at a free surface of the thin layer and extending over a depth such that each trench passes through the thin layer and the buried oxide layer, these primary trenches delimiting at least one island of the SeOI substrate, forming a mask inside the primary trenches and as a layer covering the areas of the free surface of the thin layer located outside the islands, proceeding with heat treatment for dissolving the buried oxide layer present at the island, so as to reduce the thickness thereof.

Abstract: Methods of bonding together semiconductor structures include annealing a first metal feature on a first semiconductor structure, bonding the first metal feature to a second metal feature of a second semiconductor structure to form a bonded metal structure that comprises the first metal feature and the second metal feature, and annealing the bonded metal structure. Annealing the first metal feature may comprise subjecting the first metal feature to a pre-bonding thermal budget, and annealing the bonded metal structure may comprise subjecting the bonded metal structure to a post-bonding thermal budget that is less than the pre-bonding thermal budget. Bonded semiconductor structures are fabricated using such methods.

Abstract: A process for treating a semiconductor-on-insulator structure that has, in succession, a support substrate, a layer of an oxide or oxynitride of a semiconductor material, and a thin semiconductor layer of the semiconductor material. The process includes providing, on the surface of the thin layer, a mask defining exposed regions of the thin layer; providing a layer of nitride or oxynitride of the semiconductor material on the exposed regions of the thin layer; and applying a heat treatment causing at least some of the oxygen in the oxide or oxynitride layer to diffuse through the exposed regions. The nitride or oxynitride layer is provided at a thickness sufficient to provide a ratio of the rate of oxygen diffusion though the exposed regions to that through the regions covered with the mask that is greater than 2.

Abstract: The invention relates to a structure and a process for measuring an energy of adhesion between two substrates bonded in a transverse direction. The method involves providing for at least one of the two substrates to have a plurality of elementary test cells within a test layer each being capable of locally applying, in the transverse direction, a preset mechanical stress (?), dependent on the temperature (T), to a bond interface between the substrates in a direction tending to separate them, applying a test temperature to the substrates and identifying debonded regions of the bond interface so that the local adhesion energy at the test temperature in the regions may be deduced therefrom, the local adhesion energy in a region of the bond interface being deduced from the stress applied by the test cells that caused debonding in the region.

Abstract: The invention relates to a process for fabricating a semiconductor that comprises providing a handle substrate comprising a seed substrate and a weakened sacrificial layer covering the seed substrate; joining the handle substrate with a carrier substrate; optionally treating the carrier substrate; detaching the handle substrate at the sacrificial layer to form the semiconductor structure; and removing any residue of the sacrificial layer present on the seed substrate.

Abstract: A process for treating a semiconductor-on-insulator type structure that includes, successively, a support substrate, an oxide layer and a thin semiconductor layer. The process includes formation of a silicon nitride or silicon oxynitride mask on the thin semiconductor layer to define exposed areas at the surface of the layer which are not covered by the mask, and which are arranged in a desired pattern; and application of a heat treatment in a neutral or controlled reducing atmosphere and under controlled conditions of temperature and time to induce at least a portion of the oxygen of the oxide layer to diffuse through the thin semiconductor layer, thereby resulting in the controlled reduction in the oxide thickness in the areas of the oxide layer corresponding to the desired pattern. The mask is formed so as to be at least partially buried in the thickness of the thin semiconductor layer.

Abstract: Methods of bonding together semiconductor structures include annealing a first metal feature on a first semiconductor structure, bonding the first metal feature to a second metal feature of a second semiconductor structure to form a bonded metal structure that comprises the first metal feature and the second metal feature, and annealing the bonded metal structure. Annealing the first metal feature may comprise subjecting the first metal feature to a pre-bonding thermal budget, and annealing the bonded metal structure may comprise subjecting the bonded metal structure to a post-bonding thermal budget that is less than the pre-bonding thermal budget. Bonded semiconductor structures are fabricated using such methods.

Abstract: Methods of bonding together semiconductor structures include annealing metal of a feature on a semiconductor structure prior to directly bonding the feature to a metal feature of another semiconductor structure to form a bonded metal structure, and annealing the bonded metal structure after the bonding process. The thermal budget of the first annealing process may be at least as high as a thermal budget of a later annealing process. Additional methods involve forming a void in a metal feature, and annealing the metal feature to expand the metal of the feature into the void. Bonded semiconductor structures and intermediate structures are formed using such methods.

Abstract: A process for treating a semiconductor-on-insulator structure that has, in succession, a support substrate, a layer of an oxide or oxynitride of a semiconductor material, and a thin semiconductor layer of the semiconductor material. The process includes providing, on the surface of the thin layer, a mask defining exposed regions of the thin layer; providing a layer of nitride or oxynitride of the semiconductor material on the exposed regions of the thin layer; and applying a heat treatment causing at least some of the oxygen in the oxide or oxynitride layer to diffuse through the exposed regions. The nitride or oxynitride layer is provided at a thickness sufficient to provide a ratio of the rate of oxygen diffusion though the exposed regions to that through the regions covered with the mask that is greater than 2.

Abstract: A process for treating a semiconductor-on-insulator type structure that includes, successively, a support substrate, an oxide layer and a thin semiconductor layer. The process includes formation of a silicon nitride or silicon oxynitride mask on the thin semiconductor layer to define exposed areas at the surface of the layer which are not covered by the mask, and which are arranged in a desired pattern; and application of a heat treatment in a neutral or controlled reducing atmosphere and under controlled conditions of temperature and time to induce at least a portion of the oxygen of the oxide layer to diffuse through the thin semiconductor layer, thereby resulting in the controlled reduction in the oxide thickness in the areas of the oxide layer corresponding to the desired pattern. The mask is formed so as to be at least partially buried in the thickness of the thin semiconductor layer.