According to one embodiment, a MEMS element includes a base body, a supporter, a film part, a first electrode, a second electrode, and an insulating member. The supporter is fixed to the base body. The film part is separated from the base body in a first direction and supported by the supporter. The first electrode is fixed to the base body and provided between the base body and the film part. The second electrode is fixed to the film part and provided between the first electrode and the film part. The insulating member includes a first insulating region and a second insulating region. The first insulating region is provided between the first electrode and the second electrode. A first gap is provided between the first insulating region and the second electrode. The second insulating region does not overlap the first electrode in the first direction.

A microelectromechanical systems (MEMS) die includes a substrate, a back plate, and a diaphragm. The back plate is coupled to the substrate and includes a dielectric layer and an electrode. The electrode is coupled to the dielectric layer and defines an opening that exposes a central portion of the dielectric layer. The diaphragm is oriented parallel to the back plate and is spaced apart from the back plate. In one implementation, a diameter of the opening is greater than or equal to 1/10 of the diameter of the diaphragm.

The physical quantity sensor includes a movable body oscillating around an oscillation axis, and a detection electrode disposed so as to be opposed to the movable body. The substrate has a first area through an m-th area, and the detection electrode is disposed so as to straddle the first area through an n-th area. When setting a first imaginary straight line which is the smallest in an angle formed with an X-axis direction out of imaginary straight lines connecting two of end parts on respective areas of the first area through the n-th area of the detection electrode, and a second imaginary straight line extending along a principal surface located at the substrate side of the movable body in a state in which the movable body makes a maximum displacement around the oscillation axis, the first imaginary straight line and the second imaginary straight line fail to cross each other in an area between a first normal line which passes the end part of the first area, and which extends in the Z-axis direction, and a second normal line which passes the end part in the n-th area, and which extends in the Z-axis direction.

Various embodiments of the present disclosure are directed towards a microelectromechanical system (MEMS) device. The MEMS device includes a dielectric structure disposed over a first semiconductor substrate, where the dielectric structure at least partially defines a cavity. A second semiconductor substrate is disposed over the dielectric structure. The second semiconductor substrate includes a movable mass, where opposite sidewalls of the movable mass are disposed between opposite sidewall of the cavity. An anti-stiction structure is disposed between the movable mass and the dielectric structure, where the anti-stiction structure is a first silicon-based semiconductor.

Devices and methods of operating partitioned actuator plates to obtain a desirable shape of a movable component of a micro-electro-mechanical system (MEMS) device. The subject matter described herein can in some embodiments include a micro-electro-mechanical system (MEMS) device including a plurality of actuation electrodes attached to a first surface, where each of the one or more actuation electrode being independently controllable, and a movable component spaced apart from the first surface and movable with respect to the first surface. Where the movable component further includes one or more movable actuation electrodes spaced apart from the plurality of fixed actuation electrodes.

The present subject matter relates to devices, systems, and methods for isolation of electrostatic actuators in MEMS devices to reduce or minimize dielectric charging. A tunable component can include a fixed actuator electrode positioned on a substrate, a movable actuator electrode carried on a movable component that is suspended over the substrate, one or more isolation bumps positioned between the fixed actuator electrode and the movable actuator electrode, and a fixed isolation landing that is isolated within a portion of the fixed actuator electrode that is at, near, and/or substantially aligned with each of the one or more isolation bumps. In this arrangement, the movable actuator electrode can be selectively movable toward the fixed actuator electrode, but the one or more isolation bumps can prevent contact between the fixed and movable actuator electrodes, and the fixed isolation landing can inhibit the development of an electric field in the isolation bump.

A MEMS sensor including a diaphragm, a base surface area of the diaphragm being delimited with the aid of a peripheral wall structure, and the base surface area including at least two subareas, of which at least one of the subareas is deflectably situated, and the at least two subareas being separated from one another with the aid of at least one separating structure or being delimited by the latter. The separating structure includes at least one fluid through-opening for the passage of fluid.

A MEMS micro-mirror device includes a middle substrate, a movable structure, at least one stopper coupled with the movable structure, at least one flexure, an upper cap, and a lower cap. The movable structure includes a micro-mirror plate having a reflective surface. The flexure connects the stopper and the middle substrate. The upper cap, bonded with the middle substrate, has a first opening for allowing the movable structure's movement and has at least one first recess facing a first side of the flexure and a first side of the stopper. The lower cap, bonded with the middle substrate, has a second opening for allowing space for the movement and has at least one second recess facing a second side of the flexure and a second side of the stopper.

A MEMS capacitance microphone includes a substrate, a diaphragm, a back plate structure and a plurality of support structures. The substrate is provided with a plurality of gate structures and a cavity penetrating through the substrate, and the gate structures extend from an inner wall of the cavity to the center of the cavity. The diaphragm is vibratably arranged on one side of the substrate and includes a main deformation zone and a non-main deformation zone. The back plate structure is arranged on the diaphragm, and the diaphragm is located between the substrate and the back plate structure. The support structures are arranged on the back plate structure, penetrate the periphery of the main deformation zone, and respectively abut against the gate structures. The MEMS capacitance microphone has higher rigidity of a back plate, and is capable of greatly reducing the impedance of air to increase its signal-to-noise ratio.

A physical quantity sensor includes, when three directions orthogonal to one another are defined as a first direction, a second direction, and a third direction, a substrate; and a moving member facing the substrate in the third direction via a gap and becoming displaced in the third direction in relation to the substrate. The moving member has a first region that has a plurality of penetration holes penetrating the moving member in the third direction and having a square opening shape as viewed from the third direction, and a second region having no penetration hole. At least one of a length in the first direction and a length in the second direction of the second region is equal to or greater than S0+2×S1, where S0 is a length of one side of the penetration hole, and S1 is a space between the penetration holes next to each other.