A device includes a microelectromechanical system (MEMS) sensor die comprising a deformable membrane, a MEMS heating element, and a substrate. The MEMS heating element is integrated within a same layer and a same plane as the deformable membrane. The MEMS heating element surrounds the deformable membrane and is separated from the deformable membrane through a trench. The MEMS heating element is configured to generate heat to heat up the deformable membrane. The substrate is coupled to the deformable membrane.

A method for producing a microelectromechanical component as well as a wafer system includes steps of: providing a first wafer having a plurality of microelectromechanical base elements; forming a respective container structure on the microelectromechanical base elements at the wafer level; and disposing an oil or a gel within the container structures.

A micro-electro mechanical system (MEMS) scanner has a backside reinforcement structure configured to concentrate stress which is exerted against the reinforcement structure at contour points. The reinforcement structure is attached to an underside of a mirror to maintain mirror flatness. Characteristics and features of the contour points are variable based on the specific application, including considerations for the design of the MEMS scanner, mirror, and reinforcement structure. The contour points are configured for concentration of stress to relieve stress from relatively weaker areas on the reinforcement structure, thereby increasing reliability and performance of the MEMS scanner. For example, a point of failure on the reinforcement structure may be where a top silicon layer and transition layer (e.g., silicon oxide layer) adjoin. Implementation of the contour points can concentrate stress at the contour points and thereby relieve stress from the weaker areas.

The present invention discloses an MEMS pressure sensing element, including a substrate provided with a groove; a pressure-sensitive film disposed above the substrate, the pressure-sensitive film sealing an opening of the groove to form a sealed cavity; and a movable electrode plate and a fixed electrode plate which are located in the sealed cavity and form a capacitor structure, wherein the fixed electrode plate is fixed on a bottom wall of the groove of the substrate, and the movable electrode plate is suspended above the fixed electrode plate and opposite to the fixed electrode plate; and the pressure-sensitive film is connected to the movable electrode plate so as to drive the movable electrode plate to move under the action of an external pressure. According to the MEMS pressure sensing element, pressure sensitivity and electrical detection are separated, the pressure-sensitive film is exposed in air, the capacitor structures are disposed in the sealed cavity defined by the pressure-sensitive film and the substrate, and the movable electrode plates of the capacitor structures can be driven by the pressure-sensitive film. In this way, not only is a pressure-sensitive function finished, but also external electromagnetic interferences on the capacitor structures are shielded.

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.

A microelectromechanical system includes a housing with an access opening and a sound transducer with a membrane and a backplate, wherein the sound transducer is coupled to the access opening. The microelectromechanical system includes a filter arranged between the access opening and the sound transducer and includes a filter material and a pretension element, the pretension element being mechanically connected to the filter material, and wherein the pretension element produces stress in the filter material in order to provide a bending deformation of the filter in a direction away from the backplate.

Provided are a MEMS microphone chip and an MEMS microphone. The MEMS microphone chip comprises a substrate, a backplate and a vibration diaphragm, the backplate and the vibration diaphragm constituting two electrodes of a capacitor respectively, the backplate and the vibration diaphragm being suspended above the substrate, the backplate being located between the substrate and the vibration diaphragm, and the substrate being provided with a back chamber and a support column, the support column being connected to a side wall of the back chamber via a connection portion, a through hole or a notch being formed in the connection portion through its thickness direction, to allow spaces at opposite sides of the connection portion to communicate with each other; and the support column being configured to support the backplate.

A micro-electro-mechanical sensor comprises a first substrate comprising an element movable with respect to the first substrate and a second substrate comprising a first contact pad and a second contact pad. The first substrate is bonded to the second substrate such that a movement of the element changes a coupling between the first contact pad and the second contact pad.

Active superhydrophobic surface structures are actively-controlled surface structures exhibiting a superhydrophobic state and an ordinary state. Active superhydrophobic surface structures comprise an outer elastomeric covering defining an exposed surface, a controlled group of MEMS (micro-electro-mechanical system) actuators at least covered by the elastomeric covering, and, a controlled region of the exposed surface corresponding to the controlled group. The controlled region has a superhydrophobic state in which the controlled region is textured. The controlled region also has an ordinary state in which the controlled region is smooth (i.e., less textured than in the superhydrophobic state). Active superhydrophobic surface structures may be part of an apparatus that includes a controller and/or one or more sensors. The controller, sensors, and the controlled region may form a feedback loop in which the active superhydrophobic surface is actively controlled.

A multi-layer, stress-isolation platform configured for attaching a MEMS die to a base includes a first platform, a first layer of attachment material between the base and the first platform and attaching the first platform to the base, a MEMS die, and a second layer of attachment material between the first platform and the MEMS die and attaching the MEMS die to the first platform.