Abstract: A method for manufacturing an integrated electronic device. The method includes providing an SOI substrate having a semiconductor substrate, an insulating layer on the semiconductor substrate, and a semiconductor starting layer on the insulating layer; epitaxially growing the starting layer to obtain a semiconductor active layer on the insulating layer for integrating components of the device, and forming at least one contact trench extending from an exposed surface of the starting layer to the semiconductor substrate before the step of epitaxially growing the starting layer, wherein each contact trench clears a corresponding portion of the starting layer, of the insulating layer and of the semiconductor substrate, the epitaxial growing being further applied to the cleared portions thereby at least partially filling the at least one contact trench with semiconductor material.

Abstract: A vertical-gate MOS transistor is integrated in a semiconductor chip of a first conductivity type having a main surface, and includes an insulated trench gate extending into the semiconductor chip from the main surface to a gate depth. The trench gate includes a control gate and an insulation layer for insulating the control gate from the semiconductor chip, source and drain regions of a second conductivity type formed in the semiconductor chip, at least one of the source and drain regions being adjacent to the insulation layer and extending into the semiconductor chip from the main surface to a region depth lower than the gate depth. The insulation layer includes an outer portion, extending into the semiconductor chip to a protection depth less than the gate depth, and an inner portion, the outer portion having first thickness and the internal portion having a second thickness less than the first thickness.

Abstract: A method manufactures a vertical-gate MOS transistor integrated in a semiconductor chip having a main surface. The method includes: forming a trench gate extending into the chip from the main surface to a gate depth, by forming a control gate and an insulation layer for insulating the control gate from the chip. Forming the trench gate includes: forming a trench extending into the chip from the main surface to a protection depth less than the gate depth, the trench having a lateral wall and a bottom wall with an edge portion of the lateral wall extending from the main surface being inclined outwardly with respect to the remaining portion of the lateral wall; forming a first auxiliary insulation layer in the trench; removing a bottom wall of the first auxiliary insulation layer; extending the trench to the gate depth; and forming a second auxiliary insulation layer in the trench.

Abstract: A process for the fabrication of an integrated device in a semiconductor chip envisages: forming a semiconductor layer partially suspended above a semiconductor substrate and constrained to the substrate by temporary anchorages; dividing the layer into a plurality of portions laterally separated from one another; and removing the temporary anchorages, in order to free the portions.

Abstract: An insulated-gate transistor includes a semiconductor layer of a first conductivity type, an insulated gate comprising a trench gate extending into the semiconductor layer, a source and a drain regions of a second conductivity type formed in the semiconductor layer at respective sides of the trench gate, wherein each one of the source and drain regions includes a first doped region, having a first dopant concentration, formed in the semiconductor layer adjacent to the trench gate, said first dopant concentration being such that a breakdown voltage of the junction formed by the first doped region and the semiconductor layer is higher than a predetermined breakdown voltage, and a second doped region, having a second dopant concentration higher than the first dopant concentration, said second doped region being formed in the first doped region and being spaced apart from the trench gate, the second dopant concentration being adapted to form a non-rectifying contact for electrically contacting the first doped reg

Abstract: An optoelectronic module includes a first sub-module and a second sub-module. The first sub-module has a surface with a cavity formed therein, and includes an integrated waveguide provided with a first optical port accessible from the cavity. The second sub-module faces the first sub-module. A metallic wall extends from the first sub-module to the second sub-module, and surrounds the cavity to define a hermetically closed chamber. An optoelectronic device is coupled to at least one of the first and second sub-modules, and is included in the chamber. The optoelectronic may comprise a second optical port coupled to the first optical port in the first sub-module.

Abstract: A packaging structure for optoelectronic components is formed by a first body, of semiconductor material, and a second body, of semiconductor material, fixed to a first face of said first body. A through window is formed in the second body and exposes a portion of the first face of the first body, whereon at least one optoelectronic component is fixed. Through connection regions extend through the first body and are in electrical contact with the optoelectronic component. The through connection regions are insulated from the rest of the first body via through insulation regions. Contact regions are arranged on the bottom face of the first body and are connected to said optoelectronic component via the through connection regions.

Abstract: A method of fabricating a wafer-size photovoltaic cell module includes defining an integrated cellular structure of a light converting monolateral or bilateral junction diode in an epitaxially grown detachable layer including a first deposited metal current collecting terminal of the diode. The method also includes laminating onto the surface of the processed epitaxially grown detachable layer a film of an optical grade plastic material resistant to hydrofluoric acid solutions. The method further includes immersing the wafer in a hydrofluoric acid solution causing detachment of the epitaxially grown silicon layer laminated with the film, and polishing the surface of separation of the detached epitaxially grown layer and forming a second metal current collecting terminal of the diode by masked deposition of a metal at a temperature tolerable by the film.

Abstract: A waveguide core having a high coupling efficiency is disclosed. A method of manufacturing such a waveguide includes successive deposition of multiple layers of silicon dioxide. Deposition of each layer is followed by implantation of dopant impurities in a pre-established area of the layer. After deposition and implantation, high-temperature treatment is performed to diffuse the dopant impurities. The reciprocal position of the pre-established areas and the implantation dosage and energy are selected such that the refractive index of the core in the terminal segment varies gradually in a longitudinal direction, increasing towards the input/output ends of the waveguide.

Abstract: The described process allows trenches to be etched in a structure comprising a support substrate and a multilayer, formed on the substrate, for the definition of wave guides of an integrated optical device and comprises a selective plasma attack in the multilayer through a masking structure that leaves uncovered areas of the multilayer corresponding to the trenches to be etched. Such a masking structure is obtained by forming a mask of metallic material on the multilayer that leaves uncovered the areas corresponding to the trenches to be etched and forming a mask of non-metallic material, for example photoresist, on it that leaves uncovered regions comprising at least part of the areas and an edge portion of the mask of metallic material.

Abstract: A packaging structure for optoelectronic components is formed by a first body, of semiconductor material, and a second body, of semiconductor material, fixed to a first face of said first body. A through window is formed in the second body and exposes a portion of the first face of the first body, whereon at least one optoelectronic component is fixed. Through connection regions extend through the first body and are in electrical contact with the optoelectronic component. The through connection regions are insulated from the rest of the first body via through insulation regions. Contact regions are arranged on the bottom face of the first body and are connected to said optoelectronic component via the through connection regions.

Abstract: A method of producing a wave guide integrated in a substrate, includes the phases of forming a lower cladding of the guide supported by the substrate and forming a core of the guide by means of a doped material, the core extending along an axis of propagation and having a rounded cross section. The method is characterized in that said phase of forming the core includes the phases of attacking said lower cladding to define a concave region delimited by a curved surface and extending along the axis of propagation, and providing on a free surface of said lower cladding a layer of doped material filling the concave region to form a first portion of the core in contact with the curved surface.

Abstract: Method for manufacturing an SOI wafer. On a monocrystalline silicon wafer, forming protective regions having the shape of an overturned U, made of an oxidation resistant material, the protective regions covering first wafer portions. Forming deep trenches in the wafer which extend between, and laterally delimit the first wafer portions, completely oxidizing the first wafer portions except their upper areas which are covered by the protective regions, to form at least one continuous region of covered oxide overlaid by the non-oxidized upper portions. Removing the protective regions, and epitaxially growing a crystalline semiconductor material layer from the non-oxidized upper portions.

Abstract: A method for the formation of a region of silicon dioxide on a substrate of monocrystalline silicon. The epitaxial growth of a silicon layer, the opening of holes in the silicon layer above the silicon dioxide region, and the removal of the silicon dioxide which constitutes the region by means of chemical attack through the holes until a silicon diaphragm, attached to the substrate along the edges and separated therefrom by a space, is produced. In order to form an absolute pressure microsensor, the space has to be sealed. To do this, the method provides for the holes to have diameters smaller than the thickness of the diaphragm and to be closed by the formation of a silicon dioxide layer by vapor-phase deposition at atmospheric pressure.

Abstract: Method for manufacturing an SOI wafer. On a monocrystalline silicon wafer, forming protective regions having the shape of an overturned U, made of an oxidation resistant material, the protective regions covering first wafer portions. Forming deep trenches in the wafer which extend between, and laterally delimit the first wafer portions, completely oxidizing the first wafer portions except their upper areas which are covered by the protective regions, to form at least one continuous region of covered oxide overlaid by the non-oxidized upper portions. Removing the protective regions, and epitaxially growing a crystalline semiconductor material layer from the non-oxidized upper portions.

Abstract: The method is based on the use of an etching mask comprising silicon carbide or titanium nitride for removing a sacrificial region. In case of manufacture of integrated semiconductor material structures, the following steps are performed: forming a sacrificial region of silicon oxide on a substrate of semiconductor material; growing a pseudo-epitaxial layer; forming electronic circuit components; depositing a masking layer comprising silicon carbide or titanium nitride; defining photolithographically the masking layer so as to form an etching mask containing the topography of a microstructure to be formed; with the etching mask, forming trenches in the pseudo-epitaxial layer as far as the sacrificial region so as to laterally define the microstructure; and removing the sacrificial region through the trenches.

Abstract: An angular speed sensor comprises a pair of mobile masses which are formed in an epitaxial layer and are anchored to one another and to the remainder of the device by anchorage elements. The mobile masses are symmetrical with one another, and have first mobile excitation electrodes which are intercalated with respective first fixed excitation electrodes and second mobile detection electrodes which are intercalated with second fixed detection electrodes. The first mobile and fixed excitation electrodes extend in a first direction and the second mobile and fixed detection electrodes extend in a second direction which is perpendicular to the first direction and is disposed on a single plane parallel to the surface of the device.

Abstract: An angular speed sensor comprises a pair of mobile masses which are formed in an epitaxial layer and are anchored to one another and to the remainder of the device by anchorage elements. The mobile masses are symmetrical with one another, and have first mobile excitation electrodes which are intercalated with respective first fixed excitation electrodes and second mobile detection electrodes which are intercalated with second fixed detection electrodes. The first mobile and fixed excitation electrodes extend in a first direction and the second mobile and fixed detection electrodes extend in a second direction which is perpendicular to the first direction and is disposed on a single plane parallel to the surface of the device.

Abstract: On a substrate of semiconductor material, a sacrificial region is formed and an epitaxial layer is grown; a stress release trench is formed, surrounding an area of the epitaxial layer, where an integrated electromechanical microstructure is to be formed; the wafer is then heat treated, to release residual stress. Subsequently, the stress release trench is filled with a sealing region of dielectric material, and integrated components are formed. Finally, inside the area surrounded by the sealing region, a microstructure definition trench is formed, and the sacrificial region is removed, thus obtaining an integrated microstructure with zero residual stress.

Abstract: The method is based on the use of an etching mask comprising silicon carbide or titanium nitride for removing a sacrificial region. In case of manufacture of integrated semiconductor material structures, the following steps are performed: forming a sacrificial region of silicon oxide on a substrate of semiconductor material; growing a pseudo-epitaxial layer; forming electronic circuit components; depositing a masking layer comprising silicon carbide or titanium nitride; defining photolithographically the masking layer so as to form an etching mask containing the topography of a microstructure to be formed; with the etching mask, forming trenches in the pseudo-epitaxial layer as far as the sacrificial region so as to laterally define the microstructure; and removing the sacrificial region through the trenches.