A method of forming an ultrasound transducer device includes bonding a membrane to a substrate so as to form a sealed cavity between the membrane and the substrate. An exposed surface located within the sealed cavity includes a getter material that is electrically isolated from a bottom electrode of the cavity.

A piezoelectric MEMS microphone comprising a multi-layer sensor that includes at least one piezoelectric layer between two electrode layers, with the sensor being dimensioned such that it provides a near maximized ratio of output energy to sensor area, as determined by an optimization parameter that accounts for input pressure, bandwidth, and characteristics of the piezoelectric and electrode materials. The sensor can be formed from single or stacked cantilevered beams separated from each other by a small gap, or can be a stress-relieved diaphragm that is formed by deposition onto a silicon substrate, with the diaphragm then being stress relieved by substantial detachment of the diaphragm from the substrate, and then followed by reattachment of the now stress relieved diaphragm.

CMOS Ultrasonic Transducers and processes for making such devices are described. The processes may include forming cavities on a first wafer and bonding the first wafer to a second wafer. The second wafer may be processed to form a membrane for the cavities. Electrical access to the cavities may be provided.

A ceramic substrate is mainly constituted of ceramic, and has a first main surface and a second main surface located opposite to the first main surface. A recessed portion recessed toward a first main surface side is formed in the second main surface. A wire portion extending from an outer peripheral surface of the ceramic substrate to inside of the recessed portion is formed, and a bottom portion located on the first main surface side in the recessed portion has a portion thinner than another portion of the ceramic substrate other than the bottom portion.

A MEMS device includes a first multi-layer structure, a second multi-layer structure over the first multi-layer structure, a first semiconductor layer between the first and second multilayer structures, a first air gap separating the first multi-layer structure and the first semiconductor layer, a second air gap separating the first semiconductor layer and the second multi-layer structure, a plurality of semiconductor pillars, and a plurality of second semiconductor pillars. The first semiconductor pillars are exposed to the first air gap, and coupled to the first semiconductor layer and the first multi-layer structure. The second semiconductor pillars are exposed to the second air gap, and coupled to the first semiconductor layer and the second multi-layer structure.

A cell includes a membrane and an actuating layer. The membrane includes a first membrane subpart and a second membrane subpart, wherein the first membrane subpart and the second membrane subpart are opposite to each other. The actuating layer is disposed on the first membrane subpart and the second membrane subpart. The first membrane subpart includes a first anchored edge which is fully or partially anchored, and edges of the first membrane subpart other than the first anchored edge are non-anchored. The second membrane subpart includes a second anchored edge which is fully or partially anchored, and edges of the second membrane subpart other than the second anchored edge are non-anchored.

A method of manufacturing a microelectromechanical component, the method may include: forming a mask over a layer, the mask comprising a structured surface; heating a region of the mask comprising the structured surface above a glass transition temperature of the mask to smooth out edges of the structured surface to form a corrugated surface; etching the layer covered by the mask, the etching removing the mask to carry over the corrugated surface of the mask into the layer and to form a corrugated surface of the layer; forming a diaphragm over the layer to form a corrugated region of the diaphragm configured to actuate; and forming an electrically-conductive component configured to at least one of: provide a force to actuate the diaphragm in response to an electrical signal transmitted to the electrically-conductive component and provide an electrical signal in response to an actuation of the diaphragm.

A structure for fixing a membrane to a carrier including a carrier; a suspended structure; and a holding structure with a rounded concave shape which is configured to fix the suspended structure to the carrier and where a tapered side of the holding structure physically connects to the suspended structure is disclosed. A method of forming the holding structure on a carrier to support a suspended structure is further disclosed. The method may include: forming a holding structure on a carrier; forming a suspended structure on the holding structure; shaping the holding structure such that it has a concave shape; and arranging the holding structure such that a tapered side of the holding structure physically connects to the suspended structure.

Multiple degenerately-doped silicon layers are implemented within resonant structures to control multiple orders of temperature coefficients of frequency.

A MEMS device and a method for manufacturing a MEMS device are provided. The MEMS device includes an anchor, a diaphragm structure, and a sealing film. The diaphragm structure is disposed over the anchor and has an opening through the diaphragm structure. The sealing film covers at least a portion of the opening of the diaphragm structure.