Abstract: The pressure sensor is integrated in an SOI (Silicon-on-Insulator) substrate using the insulating layer as a sacrificial layer, which is partly removed by chemical etching to form the diaphragm. To fabricate the sensor, after forming the piezoresistive elements and the electronic components integrated in the same chip, trenches are formed in the upper wafer of the substrate and extending from the surface to the layer of insulating material; the layer of insulating material is chemically etched through the trenches to form an opening beneath the diaphragm; and a dielectric layer is deposited to outwardly close the trenches and the opening. Thus, the process is greatly simplified, and numerous packaging problems eliminated.

Abstract: A sensor with a movable microstructure including a sensitive element, formed in a first chip of semiconductor material for producing an electrical signal dependent on a movement of at least one movable microstructure relative to a surface of the first chip. The sensitive element is enclosed in a hollow hermetic structure, and circuitry for processing the electrical signal is formed in a second chip of semiconductor material. The hollow hermetic structure includes a metal wall disposed on the surface of the first chip around the sensitive element, and the second chip is fixed to the metal wall.

Abstract: The method is intended for manufacturing a microintegrated structure, typically a microactuator for a hard-disk drive unit and includes the steps of: forming interconnection regions in a substrate of semiconductor material; forming a monocrystalline epitaxial region; forming lower sinker regions in the monocrystalline epitaxial region and in direct contact with the interconnection regions; forming insulating material regions on a structure portion of the monocrystalline epitaxial region; growing a pseudo-epitaxial region formed by a polycrystalline portion above the structure portion of the monocrystalline epitaxial region and elsewhere a monocrystalline portion; and forming upper sinker regions in the polycrystalline portion of the pseudo-epitaxial region and in direct contact with the lower sinker regions. In this way no PN junctions are present inside the polycrystalline portion of the pseudo-epitaxial region and the structure has a high breakdown voltage.

Abstract: A crystalline propylene copolymer composition having MFR L values from 2 to 15 g/10 min. and comprising (percent by weight): A) 20-80% of one or more propylene copolymers; B) 20-80% of one or more propylene copolymers with different comonomer(s) content than in A); the said MFR L values (MFR L (2)) being obtained by subjecting to degradation a precursor composition comprising the same components A) and B) in the above said proportions, but having MFR L values (MFR L (1)) from 0.3 to 5 g/10 min., with a ratio MFR L (2) to MFR L (1) of from 2 to 20.

Abstract: A polyolefin composition comprising (percentage by weight): (A) from 40 to 60% of a broad molecular weight distribution propylene polymer (component A) having a polydispersity index from 5 to 15 and melt flow rate of from 80 to 200 g/10 min (according to ASTM-D 1238, condition L); and (B) from 40 to 60% of a partially xylene-insoluble olefin polymer rubber (component B) containing at least 65% by weight of ethylene; the IVS/IVA ratio between the intrinsic viscosity (IVS) of the portion soluble in xylene of the polyolefin composition at room temperature and the intrinsic viscosity (IVA) of component (A) ranging from 2 to 2.5, both values on intrinsic viscosity being measured in tetrahydronaphthalene at 135° C. Said composition finds application in automotive field.

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: The integrated inductor comprises a coil of metal which is formed in the second metal level. The coil is supported by a bracket extending above spaced from a semiconductor material body by an air gap obtained by removing a sacrificial region formed in the first metal level. The bracket is carried by the semiconductor material body through support regions which are arranged peripherally on the bracket and are separated from one another by through apertures which are connected to the air gap. A thick oxide region extends above the semiconductor material body, below the air gap, to reduce the capacitive coupling between the inductor and the semiconductor material body. The inductor thus has a high quality factor, and is produced by a process compatible with present microelectronics processes.

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: An inertial sensor has a sensing element formed on one surface of a chip of semiconductor material and which is movable with respect to the chip. The sensing element is enclosed in a sealed hollow structure, in which the hollow structure includes a metal wall disposed on the surface around the sensing element, and a closure plate fixed to the wall.

Abstract: The integrated microactuator has a stator and a rotor having a circular extension with radial arms which support electrodes extending in a substantially circumferential direction and interleaved with one another. For the manufacture, first a sacrificial region is formed on a silicon substrate; an epitaxial layer is then grown; the circuitry electronic components and the biasing conductive regions are formed; subsequently a portion of substrate beneath the sacrificial region is removed, forming an aperture extending through the entire substrate; the epitaxial layer is excavated to define and separate from one another the rotor and the stator, and finally the sacrificial region is removed to release the mobile structures from the remainder of the chip.

Abstract: An integrated semiconductor device comprises, reciprocally superimposed, a thermally insulating region; a thermal conduction region of a high thermal conductivity material; a passivation oxide layer; and a gas sensitive element. The thermal conduction region defines a preferential path towards the gas sensitive element for the heat generated by the heater element, thereby the heat dispersed towards the substrate is negligible during the operation of the device.

Abstract: The acceleration sensor is formed in a monocrystalline silicon wafer forming part of a dedicated SOI substrate presenting a first and second monocrystalline silicon wafer separated by an insulting layer having an air gap. A well is formed in the second wafer over the air gap and is subsequently trenched up to the air gap to release the monocrystalline silicon mass forming the movable mass of the sensor; the movable mass has two numbers of movable electrodes facing respective pluralities of fixed electrodes. In the idle condition, each movable electrode is separated by different distances from the two fixed electrodes facing the movable electrode.

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: The integrated microactuator has a stator and a rotor having a circular extension with radial arms which support electrodes extending in a substantially circumferential direction and interleaved with one another. For the manufacture, first a sacrificial region is formed on a silicon substrate; an epitaxial layer is then grown; the circuitry electronic components and the biasing conductive regions are formed; subsequently a portion of substrate beneath the sacrificial region is removed, forming an aperture extending through the entire substrate; the epitaxial layer is excavated to define and separate from one another the rotor and the stator, and finally the sacrificial region is removed to release the mobile structures from the remainder of the chip.

Abstract: A sensor having high sensitivity is formed using a suspended structure with a high-density tungsten core. To manufacture it, a sacrificial layer of silicon oxide, a polycrystal silicon layer, a tungsten layer and a silicon carbide layer are deposited in succession over a single crystal silicon body. The suspended structure is defined by selectively removing the silicon carbide, tungsten and polycrystal silicon layers. Then spacers of silicon carbide are formed which cover the uncovered ends of the tungsten layer, and the sacrificial layer is then removed.

Abstract: A movable mass forming a seismic mass is formed starting from an epitaxial layer and is covered by a weighting region of tungsten which has high density. To manufacture the mass, buried conductive regions are formed in the substrate. Then, at the same time, a sacrificial region is formed in the zone where the movable mass is to be formed and oxide insulating regions are formed on the buried conductive regions so as to partially cover them. An epitaxial layer is then grown, using a nucleus region. A tungsten layer is deposited and defined and, using a silicon carbide layer as mask, the suspended structure is defined. Finally, the sacrificial region is removed, forming an air gap.

Abstract: An optical two-dimensional position sensor including a selective optical unit which faces, and is displaceable relative to, an integrated device. The selective optical unit is formed by a polarized light source and a filter with four quadrants which permits passage of light through two quadrants only. The selective optical unit is attached to a control lever such as to translate in a plane along a first direction and a second direction, and to pivot around an axis which is orthogonal to the preceding directions. In a transparent package, the integrated device comprises a first group of sensor elements which are spaced along the first direction, a second group of sensor elements which are spaced along the second direction and a third group of sensor elements which detect an angular position of the selective optical unit.

Abstract: The pressure sensor is integrated in an SOI (Silicon-on-Insulator) substrate using the insulating layer as a sacrificial layer, which is partly removed by chemical etching to form the diaphragm. To fabricate the sensor, after forming the piezoresistive elements and the electronic components integrated in the same chip, trenches are formed in the upper wafer of the substrate and extending from the surface to the layer of insulating material; the layer of insulating material is chemically etched through the trenches to form an opening beneath the diaphragm; and a dielectric layer is deposited to outwardly close the trenches and the opening. Thus, the process is greatly simplified, and numerous packaging problems eliminated.

Abstract: An electromagnetic head for a storage device comprises a magnetic core forming a magnetic circuit, and a magnetoresistive means. The magnetic core is interrupted by an air-gap, thereby separating a first pole and second pole of the magnetic core. The magnetoresistive means is disposed in the region of the air-gap, and is connected to the magnetic core so as to be connected in the magnetic circuit.