A MEMS microphone includes a substrate having a back cavity, a vibration diaphragm system, and a housing. The vibration diaphragm system includes at least two sub-vibration diaphragm assemblies, a slit is formed between adjacent two of the at least two sub-vibration diaphragm assemblies, one end, distal from the housing, of each of the at least two sub-vibration diaphragm assemblies is fixed to a cross beam assembly, and first gaps are formed between the at least two sub-vibration diaphragm assemblies and inner sides of the housing, so that the at least two sub-vibration diaphragm assemblies form a cantilever beam structure, which increases compliance of the vibration diaphragm system and further improves sensitivity of microphones.

A semiconductor pressure sensor includes a fixed electrode placed at a principal surface of a semiconductor substrate, and a diaphragm movable through an air gap in a thickness direction of the semiconductor substrate at least in an area where the diaphragm is opposed to the fixed electrode. The diaphragm includes: a movable electrode; a first insulation film placed closer to the air gap with respect to the movable electrode; a second insulation film placed opposite to the air gap with respect to the movable electrode, the second insulation film being of a same film type as the first insulation film; and a shield film that sandwiches the second insulation film with the movable electrode.

A microstructure and a method for manufacturing the same includes: disposing a liquid film on a surface of a substrate, wherein a solid-liquid interface is formed where the liquid film is in contact with the substrate; and irradiating the substrate with a laser of a predetermined waveband to etch the substrate at the solid-liquid interface, wherein the position where the laser is irradiated on the solid-liquid interface moves at least along a direction parallel to the surface of the substrate, and the absorption rate of the liquid film for the laser is greater than the absorption rate of the substrate for the laser.

In accordance with an example embodiment of this disclosure, a micro-electro-mechanical system (MEMS) device comprises a substrate, a CMOS die, and a MEMS die, each of which comprises a top side and a bottom side. The bottom side of the CMOS die is coupled to the top side of the substrate, and the MEMS die is coupled to the top side of the CMOS die, and there is a cavity positioned between the CMOS die and the substrate. The cavity may be sealed by a sealing substance, and may be filled with a filler substance (e.g., an adhesive) that is different than the sealing substance (e.g., a gaseous or non-gaseous substance). The cavity may be fully or partially surrounded by one or more downward-protruding portions of the CMOS die and/or one or more upward-protruding portions of the substrate.

A transducer unit for a MEMS sound transducer includes a support, a transducer element connected to the support and deflectable along a reciprocation axis, a coupling element for connecting the transducer element to a diaphragm in a manner spaced apart from the transducer element, and a spring region formed between the transducer element and the coupling element, the spring region including at least one spring element, which movably connects the transducer element to the coupling element, and which includes a damping layer, which at least partially covers the spring element.

A MEMS acoustic transducer provided with: a substrate of semiconductor material, having a back surface and a front surface opposite with respect to a vertical direction; a first cavity formed within the substrate, which extends from the back surface to the front surface; a membrane which is arranged at the upper surface, suspended above the first cavity and anchored along a perimeter thereof to the substrate; and a combfingered electrode arrangement including a number of mobile electrodes coupled to the membrane and a number of fixed electrodes coupled to the substrate and facing respective mobile electrodes for forming a sensing capacitor, wherein a deformation of the membrane as a result of incident acoustic pressure waves causes a capacitive variation of the sensing capacitor. In particular, the combfingered electrode arrangement lies vertically with respect to the membrane and extends parallel thereto.

A robust MEMS transducer includes a kinetic energy diverter disposed within its frontside cavity. The kinetic energy diverter blunts or diverts kinetic energy in a mass of air moving through the frontside cavity, before that kinetic energy reaches a diaphragm of the MEMS transducer. The kinetic energy diverter renders the MEMS transducer more robust and resistant to damage from such a moving mass of air.

A package structure includes a device chip, a MEMS die, a cap structure, and an eutectic bonding layer. The MEMS die is over the device chip and includes a substrate having a plurality of cavities and a conductive layer covering a bottom surface and sidewalls of each of the cavities. The cap structure is coupled to the MEMS die, and the cap structure includes a base substrate having at least one seal ring located in the cavities and a bonding layer covering a first surface and at least part of sidewalls of the seal ring. The first surface of the seal ring faces the MEMS die. The eutectic bonding layer is located between the conductive layer and the bonding layer in the cavities. In addition, a method of manufacturing the package structure is provided.

The present disclosure discloses a MEMS microphone including a substrate with a back cavity, and an electric capacitance system arranged on the substrate. The electric capacitance system includes a back plate and a diaphragm opposite to the back plate. The back plate includes a body part, a fixing portion connected to the substrate, and a connecting portion connecting the body part and the fixing portion. The diaphragm is fixed to the substrate and located at a side of the back plate close to the substrate. The fixing portion includes a first surface away from the substrate, the first surface includes a first arc surface connected with the body part, the first arc surface protrudes toward a direction away from the substrate. Compared with the related art, MEMS microphone disclosed by the present disclosure has a better reliability.

A micromechanical device that includes a silicon substrate with an overlying oxide layer and with a micromechanical functional layer lying above same, which extend in parallel to a main extension plane, a cavity being formed at least in the micromechanical functional layer and in the oxide layer. An access channel is formed in the oxide layer and/or in the micromechanical functional layer which, starting from the cavity, extends in parallel to the main extension plane and in the process extends in a projection direction, as viewed perpendicularly to the main extension plane, all the way into an access area outside the cavity. A method for manufacturing a micromechanical device is also described.