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: The invention relates to a process for manufacturing a composite substrate comprising bonding a first substrate (10) onto a second semi-conducting substrate (30), characterized in that it includes, before bonding, the formation of a bonding layer (20) between the first and the second substrate, the bonding layer (20) comprising a plurality of islands (21) distributed over the surface of the first substrate (10) in a determined pattern and separated from one another by regions (22) of a different type, which are distributed in a complementary pattern, wherein the islands (21) are formed via a plasma treatment of the material of the first substrate (10).

Abstract: The invention relates to a method for forming a plurality of electrically conductive islands in a working layer of a multilayer structure made from semiconductor materials, with the structure including an electrically insulating layer located beneath the working layer. This method includes the steps of selectively masking certain regions of the working layer in order to define several islands therein, with each region masked from the working layer corresponding to a respective island, and then wet chemical etching of the masked working layer to form a plurality of working layer islands each surrounded by the electrically insulating layer. The invention also proposes the application of such a method to the characterization of the electrical properties of a structure, and an associated device.

Abstract: An apparatus for measuring a lifetime of charge carriers that has a measuring probe and a component for directing ultraviolet radiation to a measuring position. The measuring probe also includes at least one electrode provided at a predetermined spatial relationship to the measuring position. A microwave source is adapted to direct microwave radiation to the measuring position, a microwave detector is adapted to measure an alteration of an intensity of microwave radiation reflected at the measuring position in response to the ultraviolet radiation and a semiconductor structure holder is adapted to receive a semiconductor structure and to provide an electric contact to a portion of the semiconductor structure. Additionally, a device for moving the substrate holder relative to the measuring probe is provided for positioning at least one portion of the semiconductor structure at the measuring position.

Abstract: The present invention relates to a process for preparing semiconductor on insulator type structures that include a semiconductor layer of a donor substrate, an insulator layer and a receiver substrate. The process includes bonding of the donor substrate onto the receiver substrate, with at least one of the substrates being coated with an insulator layer, and forming at the bonding interface a so-called trapping interface of electrically active traps suitable for retaining charge carriers. The invention also relates to a semiconductor on insulator type structure that includes such a trapping interface.

Abstract: The invention specifically relates to methods of fabricating a composite substrate by providing a first insulating layer on a support substrate at a thickness of e1 and providing a second insulating layer on a source substrate at a thickness of e2, with each layer having an exposed face for bonding; providing plasma activation energy in an amount sufficient to activate a portion of the thickness of the face of the first insulating layer emp1 and a portion of the thickness of the face of the second insulating layer emp1; providing a final insulating layer by molecular bonding the activated face of the first insulating layer with the activated face of the second insulating layer; and removing a back portion of the source substrate while retaining an active layer comprising a remaining portion of the source substrate bonded to the support substrate with the final insulating layer interposed therein to form the composite substrate.

Abstract: The invention specifically relates to methods of fabricating a composite substrate by providing a first insulating layer on a support substrate at a thickness of e1 and providing a second insulating layer on a source substrate at a thickness of e2, with each layer having an exposed face for bonding; providing plasma activation energy in an amount sufficient to activate a portion of the thickness of the face of the first insulating layer emp1 and a portion of the thickness of the face of the second insulating layer emp1; providing a final insulating layer by molecular bonding the activated face of the first insulating layer with the activated face of the second insulating layer; and removing a back portion of the source substrate while retaining an active layer comprising a remaining portion of the source substrate bonded to the support substrate with the final insulating layer interposed therein to form the composite substrate.

Abstract: The invention relates to a method for fabricating a locally passivated germanium-on-insulator substrate wherein, in order to achieve good electron mobility, nitridized regions are provided at localised positions. Nitridizing is achieved using a plasma treatment. The resulting substrates also form part of the invention.

Abstract: The invention concerns a field-effect transistor with a drain, a source, a channel in electrical contact with the source and the drain, and at least one gate, so as to apply an electric field to the channel when each gate is polarized, where the channel has a multi-layer structure with at least three layers, and with at least one of the layers of the multi-layer structure having electrical properties that are substantially different from those of another layer of the multi-layer structure, and wherein a single gate or two gates are arranged substantially perpendicular to a reference plane of the channel defined by an interface plane between two layers of the multi-layer structure.

Abstract: The invention concerns a method of fabricating a composite substrate comprising at least one thin insulating layer interposed between a support substrate and an active layer of semiconductor material. The method comprises: providing a source substrate that comprises a semiconductor material and a support substrate; forming or depositing an insulating layer on the source substrate; providing recovery heat treatment of the insulating layer; providing plasma activation of a front face of the recovery heat treated insulating layer or a front face of the support substrate; molecular bonding, after the plasma activation, the front face of the insulating layer with the front face of the support substrate to form a bonded substrate; and lifting off a back portion of the source substrate from the bonded substrate to retain an active layer that comprises a remaining portion of the source substrate.

Abstract: The invention relates to a treatment method of a structure comprising a thin Ge layer on a substrate, said layer having been previously bonded with the substrate, the method comprising a treatment to improve the electrical properties of the layer and/or the interface of the Ge layer with the underlying layer, characterised in that said treatment is a heat treatment applied at a temperature between 500° C. and 600° C. for not more than 3 hours.

Abstract: The invention concerns a field-effect transistor with a drain, a source, a channel in electrical contact with the source and the drain, and at least one gate, so as to apply an electric field to the channel when each gate is polarised, where the channel has a multi-layer structure with at least three layers, and with at least one of the layers of the multi-layer structure having electrical properties that are substantially different from those of another layer of the multi-layer structure, and wherein a single gate or two gates are arranged substantially perpendicular to a reference plane of the channel defined by an interface plane between two layers of the multi-layer structure.

Abstract: The invention specifically relates to methods of fabricating a composite substrate by providing a first insulating layer on a support substrate at a thickness of e1 and providing a second insulating layer on a source substrate at a thickness of e2, with each layer having an exposed face for bonding; providing plasma activation energy in an amount sufficient to activate a portion of the thickness of the face of the first insulating layer emp1 and a portion of the thickness of the face of the second insulating layer emp1; providing a final insulating layer by molecular bonding the activated face of the first insulating layer with the activated face of the second insulating layer; and removing a back portion of the source substrate while retaining an active layer comprising a remaining portion of the source substrate bonded to the support substrate with the final insulating layer interposed therein to form the composite substrate.

Abstract: The invention concerns a method of fabricating a composite substrate comprising at least one thin insulating layer interposed between a support substrate and an active layer of semiconductor material. The method comprises: providing a source substrate that comprises a semiconductor material and a support substrate; forming or depositing an insulating layer on the source substrate; providing recovery heat treatment of the insulating layer; providing plasma activation of a front face of the recovery heat treated insulating layer or a front face of the support substrate; molecular bonding, after the plasma activation, the front face of the insulating layer with the front face of the support substrate to form a bonded substrate; and lifting off a back portion of the source substrate from the bonded substrate to retain an active layer that comprises a remaining portion of the source substrate.

Abstract: The invention relates to a method for forming a plurality of electrically conductive islands in a working layer of a multilayer structure made from semiconductor materials, with the structure including an electrically insulating layer located beneath the working layer. This method includes the steps of selectively masking certain regions of the working layer in order to define several islands therein, with each region masked from the working layer corresponding to a respective island, and then wet chemical etching of the masked working layer to form a plurality of working layer islands each surrounded by the electrically insulating layer. The invention also proposes the application of such a method to the characterization of the electrical properties of a structure, and an associated device.