A MEMS micromirror device includes a monolithic body of semiconductor material having a first main surface and a second main surface, with the monolithic body having an opening extending from the second main surface and including a suspended membrane of monocrystalline semiconductor material extending between the opening and the first main surface of the monolithic body. The suspended membrane includes a supporting frame and a mobile mass carried by the supporting frame and rotatable about an axis parallel to the first main surface, with the mobile mass having a width less than a width of the opening. A reflecting region extends over the mobile mass.

A pressure sensor designed to detect a value of ambient pressure of the environment external to the pressure sensor includes: a first substrate having a buried cavity and a membrane suspended over the buried cavity; a second substrate having a recess, hermetically coupled to the first substrate so that the recess defines a sealed cavity the internal pressure value of which provides a pressure-reference value; and a channel formed at least in part in the first substrate and configured to arrange the buried cavity in communication with the environment external to the pressure sensor. The membrane undergoes deflection as a function of a difference of pressure between the pressure-reference value in the sealed cavity and the ambient-pressure value in the buried cavity.

A method for producing a reflection-reducing layer system is disclosed. In an embodiment, a method includes depositing an organic layer on the substrate, generating a nanostructure in the organic layer by a plasma etching process, applying a cover layer to the nanostructure, wherein the organic layer, the nanostructure and the cover layer together form a reflection-reducing structure, wherein the cover layer comprises an inorganic material or an organosilicon compound, and wherein the cover layer is at least 5 nm thick and performing a post-treatment after applying the cover layer, wherein a material of the organic layer is at least partially removed, decomposed or chemically converted, and wherein an effective refractive index n.sub.eff,2 of the reflection-reducing structure after the post-treatment is smaller than an effective refractive index n.sub.eff,1 of the reflection-reducing structure before the post-treatment.

A buried cavity is formed in a monolithic body to delimit a suspended membrane. A peripheral insulating region defines a supporting frame in the suspended membrane. Trenches extending through the suspended membrane define a rotatable mobile mass carried by the supporting frame. The mobile mass forms an oscillating mass, supporting arms, spring portions, and mobile electrodes that are combfingered to fixed electrodes of the supporting frame. A reflecting region is formed on top of the oscillating mass.

An actuation structure of a MEMS electroacoustic transducer is formed in a die of semiconductor material having a monolithic body with a front surface and a rear surface extending in a horizontal plane x-y plane and defined in which are: a frame; an actuator element arranged in a central opening defined by the frame; cantilever elements, coupled at the front surface between the actuator element and the frame; and piezoelectric regions arranged on the cantilever elements and configured to be biased to cause a deformation of the cantilever elements by the piezoelectric effect. A first stopper arrangement is integrated in the die and configured to interact with the cantilever elements to limit a movement thereof in a first direction of a vertical axis orthogonal to the horizontal plane, x-y plane towards the underlying central opening.

A micro-electro-mechanical device formed in a monolithic body of semiconductor material accommodating a first buried cavity; a sensitive region above the first buried cavity; and a second buried cavity extending in the sensitive region. A decoupling trench extends from a first face of the monolithic body as far as the first buried cavity and laterally surrounds the second buried cavity. The decoupling trench separates the sensitive region from a peripheral portion of the monolithic body.

The structure of a micro-electro-mechanical system (MEMS) thermal sensor and a method of fabricating the MEMS thermal sensor are disclosed. A method of fabricating a MEMS thermal sensor includes forming first and second sensing electrodes with first and second electrode fingers, respectively, on a substrate and forming a patterned layer with a rectangular cross-section between a pair of the first electrode fingers. The first and second electrode fingers are formed in an interdigitated configuration and suspended above the substrate. The method further includes modifying the patterned layer to have a curved cross-section between the pair of the first electrode fingers, forming a curved sensing element on the modified patterned layer to couple to the pair of the first electrodes, and removing the modified patterned layer.

A method for forming a microelectromechanical systems (MEMS) device may include performing a first silicon-on-nothing process to form a first cavity in a substrate. The method may include depositing an epitaxial layer on a surface of the substrate. The method may include performing a second silicon-on-nothing process to form a second cavity in the epitaxial layer. The method may include exposing the first cavity and the second cavity by removing a portion of the substrate and the epitaxial layer.

A method for manufacturing a MEMS device includes a hole forming step of forming a plurality of holes concaved from a principal surface in a substrate material including a semiconductor, a connecting-hollow-portion forming step of forming a connecting hollow portion that connects the plurality of holes together, and a movable-portion forming step of, by partially moving the semiconductor of the substrate material so as to close at least one part of the plurality of holes, forming a hollow portion that exists inside the substrate material and a movable portion that coincides with the hollow portion when viewed in a thickness direction of the substrate material.

A method for producing a reflection-reducing layer system is disclosed. In an embodiment, a method includes depositing an organic layer on the substrate, generating a nanostructure in the organic layer by a plasma etching process, applying a cover layer to the nanostructure, wherein the organic layer, the nanostructure and the cover layer together form a reflection-reducing structure, wherein the cover layer comprises an inorganic material or an organosilicon compound, and wherein the cover layer is at least 5 nm thick and performing a post-treatment after applying the cover layer, wherein a material of the organic layer is at least partially removed, decomposed or chemically converted, and wherein an effective refractive index n.sub.eff,2 of the reflection-reducing structure after the post-treatment is smaller than an effective refractive index n.sub.eff,1 of the reflection-reducing structure before the post-treatment.