Abstract: A MEMS shutter including: a substrate of semiconductor material traversed by a main aperture, and a first semiconductor layer and a second semiconductor layer, which form a supporting structure fixed to the substrate; a plurality of deformable structures; a plurality of actuators; and a plurality of shielding structures, each of which is formed by a corresponding portion of at least one between the first semiconductor layer and the second semiconductor layer, the shielding structures being arranged angularly around the underlying main aperture so as to provide shielding of the main aperture, each shielding structure being further coupled to the supporting structure via a corresponding deformable structure. Each actuator may be controlled so as to cause a rotation of a corresponding shielding structure between a respective first position and a respective second position, thus varying shielding of the main aperture.

Abstract: A process for manufacturing a combined microelectromechanical device includes forming, in a die of semiconductor material, at least a first and a second microelectromechanical structure, performing a first bonding phase to bond a cap to the die via a bonding region or adhesive to define at least a first and a second cavity at the first and, respectively, second microelectromechanical structures, the cavities being at a controlled pressure, forming an access channel through the cap in fluidic communication with the first cavity to control the pressure value inside the first cavity in a distinct manner with respect to a respective pressure value inside the second cavity, and performing a second bonding phase, after which the bonding region deforms to hermetically close the first cavity with respect to the access channel.

Abstract: A method for manufacturing a filtering module comprising the steps of: forming a multilayer body comprising a filter layer of semiconductor material and having a thickness of less than 10 ?m, a first structural layer coupled to a first side of the filter layer, and a second structural layer coupled to a second side, opposite to the first side, of the filter layer; forming a recess in the first structural layer, which extends throughout its thickness; removing selective portions, exposed through the recess, of the filter layer to form a plurality of openings, which extend throughout the thickness of the filter layer; and completely removing the second structural layer to connect fluidically the first and second sides of the filter layer, thus forming a filtering membrane designed to inhibit passage of contaminating particles.

Abstract: A micromechanical mirror structure includes a mirror element designed to reflect an incident light radiation and a protective structure arranged over the mirror element to provide mechanical protection for the mirror element and to increase the reflectivity of the mirror element with respect to the incident light radiation. The protective structure has a first protective layer and a second protective layer which are stacked on the mirror element. The second protective layer is arranged on the first protective layer and the first protective layer is arranged on the mirror element. The layers include a respective dielectric material and having respective refractive indexes that jointly increase the reflectivity of the mirror element in a range of wavelengths of interest.

Abstract: A method for manufacturing a semiconductor die, comprising the steps of: providing a MEMS device having a structural body, provided with a cavity, and a membrane structure suspended over the cavity; coupling the structural body to a filtering module via direct bonding or fusion bonding so that a first portion of the filtering module extends over the cavity and a second portion of the filtering module extends seamlessly as a prolongation of the structural body; and etching selective portions of the filtering module in an area corresponding to the first portion, to form filtering openings fluidically coupled to the cavity. The semiconductor die is, for example, a microphone.

Abstract: A method for manufacturing a PMUT device including a piezoelectric element located at a membrane element is provided. The method includes receiving a silicon on insulator substrate having a first silicon layer, an oxide layer, and a second silicon layer. Portions of a first surface of the second silicon layer are exposed by removing exposed side portions of the first silicon layer and corresponding portions of the oxide layer, and a central portion including the remaining portions of the first silicon layer and of the oxide layer is defined. Anchor portions for the membrane element are formed at the exposed portions of the first surface of the second silicon layer. The piezoelectric element is formed above the central portion, and the membrane element is defined by selectively removing the second layer and removing the remaining portion of the oxide from under the remaining portion of the first silicon layer.

Abstract: A piezoelectric MEMS transducer formed in a body of semiconductor material, which has a central axis and a peripheral area and comprises a plurality of beams, transverse to the central axis and having a first end, coupled to the peripheral area of the body, and a second end, facing the central axis; a membrane, transverse to the central axis and arranged underneath the plurality of beams; and a pillar, parallel to the central axis and rigid with the second end of the beams and to the membrane. The MEMS transducer further comprises a plurality of piezoelectric sensing elements arranged on the plurality of beams.

Abstract: A transducer includes a supporting body and a suspended structure mechanically coupled to the supporting body. The suspended structure has a first and a second surface opposite to one another along an axis, and is configured to oscillate in an oscillation direction having at least one component parallel to the axis. A first piezoelectric transducer is disposed on the first surface of the suspended structure, and a second piezoelectric transducer is disposed on the second surface of the suspended structure.

Abstract: A microelectromechanical resonator device has: a main body, with a first surface and a second surface, opposite to one another along a vertical axis, and made of a first layer and a second layer, arranged on the first layer; a cap, having a respective first surface and a respective second surface, opposite to one another along the vertical axis, and coupled to the main body by bonding elements; and a piezoelectric resonator structure formed by: a mobile element, constituted by a resonator portion of the first layer, suspended in cantilever fashion with respect to an internal cavity provided in the second layer and moreover, on the opposite side, with respect to a housing cavity provided in the cap; a region of piezoelectric material, arranged on the mobile element on the first surface of the main body; and a top electrode, arranged on the region of piezoelectric material, the mobile element constituting a bottom electrode of the piezoelectric resonator structure.

Abstract: A piezoelectric MEMS transducer formed in a body of semiconductor material, which has a central axis and a peripheral area and comprises a plurality of beams, transverse to the central axis and having a first end, coupled to the peripheral area of the body, and a second end, facing the central axis; a membrane, transverse to the central axis and arranged underneath the plurality of beams; and a pillar, parallel to the central axis and rigid with the second end of the beams and to the membrane. The MEMS transducer further comprises a plurality of piezoelectric sensing elements arranged on the plurality of beams.

Abstract: An ultrasonic MEMS acoustic transducer formed in a body of semiconductor material having first and second surfaces opposite to one another. A first cavity extends in the body and delimits at the bottom a sensitive portion, which extends between the first cavity and the first surface of the body. The sensitive portion houses a second cavity and forms a membrane that extends between the second cavity and the first surface of the body. An elastic supporting structure extends between the sensitive portion and the body and is suspended over the first cavity.

Abstract: A piezoelectric MEMS transducer formed in a body of semiconductor material, which has a central axis and a peripheral area and comprises a plurality of beams, transverse to the central axis and having a first end, coupled to the peripheral area of the body, and a second end, facing the central axis; a membrane, transverse to the central axis and arranged underneath the plurality of beams; and a pillar, parallel to the central axis and rigid with the second end of the beams and to the membrane. The MEMS transducer further comprises a plurality of piezoelectric sensing elements arranged on the plurality of beams.

Abstract: A method for manufacturing a filtering module comprising the steps of: forming a multilayer body comprising a filter layer of semiconductor material and having a thickness of less than 10 ?m, a first structural layer coupled to a first side of the filter layer, and a second structural layer coupled to a second side, opposite to the first side, of the filter layer; forming a recess in the first structural layer, which extends throughout its thickness; removing selective portions, exposed through the recess, of the filter layer to form a plurality of openings, which extend throughout the thickness of the filter layer; and completely removing the second structural layer to connect fluidically the first and second sides of the filter layer, thus forming a filtering membrane designed to inhibit passage of contaminating particles.

Abstract: A method for manufacturing a filtering module comprising the steps of: forming a multilayer body comprising a filter layer of semiconductor material and having a thickness of less than 10 ?m, a first structural layer coupled to a first side of the filter layer, and a second structural layer coupled to a second side, opposite to the first side, of the filter layer; forming a recess in the first structural layer, which extends throughout its thickness; removing selective portions, exposed through the recess, of the filter layer to form a plurality of openings, which extend throughout the thickness of the filter layer; and completely removing the second structural layer to connect fluidically the first and second sides of the filter layer, thus forming a filtering membrane designed to inhibit passage of contaminating particles.

Abstract: A method for making a micro-electro mechanical (MEMS) device includes forming a MEMS mirror stack on a handle layer, and applying a first bonding layer to the MEMS mirror stack. The method continues with disposing a substrate on the first bonding layer such that the MEMS mirror stack is mechanically anchored to the substrate and so as to seal against ingress of environmental contaminants, removing the handle layer, and applying a second bonding layer to the MEMS mirror stack. A cap layer is disposed on the second bonding layer such that the cap layer is mechanically anchored to the MEMS mirror stack and so as to seal against ingress of environmental contaminants.

Abstract: Disclosed herein is a micro-electro mechanical (MEMS) device including a substrate, and a MEMS mirror stack on the substrate. A first bonding layer seals against ingress of environmental contaminants and mechanically anchors the MEMS mirror stack to the substrate. A cap layer is formed on the MEMS mirror stack. A second boding layer seals against ingress of environmental contaminants and mechanically anchors the cap layer to the MEMS mirror stack.

Abstract: A piezoelectric MEMS transducer formed in a body of semiconductor material, which has a central axis and a peripheral area and comprises a plurality of beams, transverse to the central axis and having a first end, coupled to the peripheral area of the body, and a second end, facing the central axis; a membrane, transverse to the central axis and arranged underneath the plurality of beams; and a pillar, parallel to the central axis and rigid with the second end of the beams and to the membrane. The MEMS transducer further comprises a plurality of piezoelectric sensing elements arranged on the plurality of beams.

Abstract: A method for manufacturing a semiconductor die, comprising the steps of: providing a MEMS device having a structural body, provided with a cavity, and a membrane structure suspended over the cavity; coupling the structural body to a filtering module via direct bonding or fusion bonding so that a first portion of the filtering module extends over the cavity and a second portion of the filtering module extends seamlessly as a prolongation of the structural body; and etching selective portions of the filtering module in an area corresponding to the first portion, to form filtering openings fluidically coupled to the cavity. The semiconductor die is, for example, a microphone.

Abstract: A micromechanical mirror structure includes a mirror element designed to reflect an incident light radiation and a protective structure arranged over the mirror element to provide mechanical protection for the mirror element and to increase the reflectivity of the mirror element with respect to the incident light radiation. The protective structure has a first protective layer and a second protective layer which are stacked on the mirror element. The second protective layer is arranged on the first protective layer and the first protective layer is arranged on the mirror element. The layers include a respective dielectric material and having respective refractive indexes that jointly increase the reflectivity of the mirror element in a range of wavelengths of interest.

Abstract: A method for manufacturing a filtering module comprising the steps of: forming a multilayer body comprising a filter layer of semiconductor material and having a thickness of less than 10 ?m, a first structural layer coupled to a first side of the filter layer, and a second structural layer coupled to a second side, opposite to the first side, of the filter layer; forming a recess in the first structural layer, which extends throughout its thickness; removing selective portions, exposed through the recess, of the filter layer to form a plurality of openings, which extend throughout the thickness of the filter layer; and completely removing the second structural layer to connect fluidically the first and second sides of the filter layer, thus forming a filtering membrane designed to inhibit passage of contaminating particles.