Abstract: A MEMS pressure transducer includes a semiconductor body, a lower dielectric region arranged above the semiconductor body, and a fixed electrode region and a lower anchoring region, which are formed by conductive material, are arranged on the lower dielectric region and are laterally separated from each other. A membrane of conductive material is suspended above the fixed electrode region so as to delimit a cavity upwardly, the fixed electrode region facing the cavity, the membrane being deformable as a function of pressure and forming a variable capacitor together with the fixed electrode region. An upper anchoring region of conductive material laterally delimits the cavity and is interposed, in direct contact, between the membrane and the lower anchoring region.

Abstract: Disclosed herein is a process flow for forming a MEMS IMU including an accelerometer and a gyroscope each located in a separate sealed cavity maintained at a different pressure. Formation of the MEMS IMU includes the use of a first vHF release to etch a sacrificial layer underneath a structural layer containing the accelerometer and gyroscope and capping the device under formation to set both cavities at a first pressure. The floor of one of the cavities is formed to including a gas permeable layer. Formation further includes forming a chimney underneath the gas permeable layer and then performing a second vHF release to etch through the gas permeable layer and expose the cavity containing the gas permeable layer so that its pressure may be set to be different than that of the other cavity when the chimney is sealed.

Abstract: A thermoelectric generator includes a substrate and one or more thermoelectric elements on the substrate and each configured to convert a thermal drop across the thermoelectric elements into an electric potential by Seebeck effect. The thermoelectric generator includes a cavity between the substrate and the thermoelectric elements. The thermoelectric generator includes, within the cavity, a support structure for supporting the thermoelectric elements. The support structure has a thermal conductivity lower than a thermal conductivity of the substrate.

Abstract: A method of fabricating a thermoelectric converter that includes providing a layer of a Silicon-based material having a first surface and a second surface, opposite to and separated from the first surface by a Silicon-based material layer thickness; forming a plurality of first thermoelectrically active elements of a first thermoelectric semiconductor material having a first Seebeck coefficient, and forming a plurality of second thermoelectrically active elements of a second thermoelectric semiconductor material having a second Seebeck coefficient, wherein the first and second thermoelectrically active elements are formed to extend through the Silicon-based material layer thickness, from the first surface to the second surface; forming electrically conductive interconnections in correspondence of the first surface and of the second surface of the layer of Silicon-based material, for electrically interconnecting the plurality of first thermoelectrically active elements and the plurality of second thermoelectri

Abstract: A method of fabricating a thermoelectric converter that includes providing a layer of a Silicon-based material having a first surface and a second surface, opposite to and separated from the first surface by a Silicon-based material layer thickness; forming a plurality of first thermoelectrically active elements of a first thermoelectric semiconductor material having a first Seebeck coefficient, and forming a plurality of second thermoelectrically active elements of a second thermoelectric semiconductor material having a second Seebeck coefficient, wherein the first and second thermoelectrically active elements are formed to extend through the Silicon-based material layer thickness, from the first surface to the second surface; forming electrically conductive interconnections in correspondence of the first surface and of the second surface of the layer of Silicon-based material, for electrically interconnecting the plurality of first thermoelectrically active elements and the plurality of second thermoelectri

Abstract: Process for manufacturing a microfluidic device, wherein a sacrificial layer is formed on a semiconductor substrate; a carrying layer is formed on the sacrificial layer; the carrying layer is selectively removed to form at least one release opening extending through the carrying layer; a permeable layer of a permeable semiconductor material is formed in the at least one release opening; the sacrificial layer is selectively removed through the permeable layer to form a fluidic chamber; the at least one release opening is filled with non-permeable semiconductor filling material, forming a monolithic body having a membrane region; an actuator element is formed on the membrane region and a cap element is attached to the monolithic body and surrounds the actuator element.

Abstract: The present disclosure is directed to a process for manufacturing a micro-electro-mechanical system (MEMS) device. The process includes, in part, forming a first sacrificial dielectric region on a semiconductor wafer; forming a structural layer of semiconductor material on the first sacrificial dielectric region; forming a plurality of first openings through the structural layer; forming a second sacrificial dielectric region on the structural layer; forming a ceiling layer of semiconductor material on the second sacrificial dielectric region; forming a plurality of second openings through the ceiling layer; forming on the ceiling layer a permeable layer; selectively removing the first and the second sacrificial dielectric regions; and forming on the permeable layer a sealing layer of semiconductor material.

Abstract: A method for manufacturing a device for ejecting a fluid, including the steps of: forming, in a first semiconductor wafer that houses a nozzle of the ejection device, a first structural layer; removing selective portions of the first structural layer to form a first portion of a chamber for containing the fluid; removing, in a second semiconductor wafer that houses an actuator of the ejection device, selective portions of a second structural layer to form a second portion of the chamber; and coupling together the first and second semiconductor wafers so that the first portion directly faces the second portion, thus forming the chamber. The first portion defines a part of volume of the chamber that is larger than a respective part of volume of the chamber defined by the second portion.

Abstract: A method of fabricating a thermoelectric converter that includes providing a layer of a Silicon-based material having a first surface and a second surface, opposite to and separated from the first surface by a Silicon-based material layer thickness; forming a plurality of first thermoelectrically active elements of a first thermoelectric semiconductor material having a first Seebeck coefficient, and forming a plurality of second thermoelectrically active elements of a second thermoelectric semiconductor material having a second Seebeck coefficient, wherein the first and second thermoelectrically active elements are formed to extend through the Silicon-based material layer thickness, from the first surface to the second surface; forming electrically conductive interconnections in correspondence of the first surface and of the second surface of the layer of Silicon-based material, for electrically interconnecting the plurality of first thermoelectrically active elements and the plurality of second thermoelectri

Abstract: A thermoelectric generator includes a substrate and one or more thermoelectric elements on the substrate and each configured to convert a thermal drop across the thermoelectric elements into an electric potential by Seebeck effect. The thermoelectric generator includes a cavity between the substrate and the thermoelectric elements. The thermoelectric generator includes, within the cavity, a support structure for supporting the thermoelectric elements. The support structure has a thermal conductivity lower than a thermal conductivity of the substrate.

Abstract: A method for manufacturing a device for ejecting a fluid, including the steps of: forming, in a first semiconductor wafer that houses a nozzle of the ejection device, a first structural layer; removing selective portions of the first structural layer to form a first portion of a chamber for containing the fluid; removing, in a second semiconductor wafer that houses an actuator of the ejection device, selective portions of a second structural layer to form a second portion of the chamber; and coupling together the first and second semiconductor wafers so that the first portion directly faces the second portion, thus forming the chamber. The first portion defines a part of volume of the chamber that is larger than a respective part of volume of the chamber defined by the second portion.

Abstract: A method for manufacturing a device for ejecting a fluid, including the steps of: forming, in a first semiconductor wafer that houses a nozzle of the ejection device, a first structural layer; removing selective portions of the first structural layer to form a first portion of a chamber for containing the fluid; removing, in a second semiconductor wafer that houses an actuator of the ejection device, selective portions of a second structural layer to form a second portion of the chamber; and coupling together the first and second semiconductor wafers so that the first portion directly faces the second portion, thus forming the chamber. The first portion defines a part of volume of the chamber that is larger than a respective part of volume of the chamber defined by the second portion.

Abstract: A method for manufacturing a device for ejecting a fluid, comprising the steps of: forming, in a first semiconductor wafer that houses a nozzle of the ejection device, a first structural layer; removing selective portions of the first structural layer to form a first portion of a chamber for containing the fluid; removing, in a second semiconductor wafer that houses an actuator of the ejection device, selective portions of a second structural layer to form a second portion of the chamber; and coupling together the first and second semiconductor wafers so that the first portion directly faces the second portion, thus forming the chamber. The first portion defines a part of volume of the chamber that is larger than a respective part of volume of the chamber defined by the second portion.