A micro-device including at least one first element comprising at least: a portion of material corresponding to a compound of at least one semi-conductor and at least one metal, first and second protective layers each covering one of two opposite faces of said portion of material, such that the first and second protective layers are in direct contact with said portion of material, that the first protective layer comprises at least one first material able to withstand an HF etching, that the second protective layer comprises at least one second material able to withstand the HF etching, and that at least one of the first and second materials able to withstand the HF etching includes the semi-conductor.

The present invention provides a MEMS pressure sensor and a manufacturing method. The pressure is formed by a top cap wafer, a MEMS wafer and a bottom cap wafer. The MEMS wafer comprises a frame and a membrane, the frame defining a cavity. The membrane is suspended by the frame over the cavity. The bottom cap wafer closes the cavity. The top cap wafer has a recess defining with the membrane a capacitance gap. The top cap wafer comprises a top cap electrode located over the membrane and forming, together with the membrane, a capacitor to detect a deflection of the membrane. Electrical contacts on the top cap wafer are connected to the top cap electrode. A vent extends from outside of the sensor into the cavity or the capacitance gap. The pressure sensor can include two cavities and two capacitance gaps to form a differential pressure sensor.

The sensor package comprises a carrier (1) including electric conductors (13), an ASIC device (6) and a sensor element (7), which is integrated in the ASIC device (6). A dummy die or interposer (4) is arranged between the carrier (1) and the ASIC device (6). The dummy die or interposer (4) is fastened to the carrier (1), and the ASIC device (6) is fastened to the dummy die or interposer (4).

The present invention provides a sound producing device comprising: an air pulse generating element and a control unit. The air pulse generating element comprises an air chamber and an actuator. The control unit, configured to generate a driving voltage applied to the actuator of the air pulse generating element, such that the air pulse generating element generates a plurality of air pulses in response to the driving voltage. The plurality of air pulses are at a pulse rate, and the pulse rate of the plurality of air pulses is higher than a maximum audible frequency.

A method of forming a monolithic integrated PMUT and CMOS with a coplanar elastic, sealing, and passivation layer in a single step without bonding and the resulting device are provided. Embodiments include providing a CMOS wafer with a metal layer; forming a dielectric over the CMOS; forming a sacrificial structure in a portion of the dielectric; forming a bottom electrode; forming a piezoelectric layer over the CMOS; forming a top electrode over portions of the bottom electrode and piezoelectric layer; forming a via through the top electrode down to the bottom electrode and a second via down to the metal layer through the top electrode; forming a second metal layer over and along sidewalls of the first and second via; removing the sacrificial structure, an open cavity formed; and forming a dielectric layer over a portion of the CMOS, the open cavity sealed and an elastic layer and passivation formed.

Microelectromechanical (MEMS) devices and associated methods are disclosed. Piezoelectric MEMS transducers (PMUTs) suitable for integration with complementary metal oxide semiconductor (CMOS) integrated circuit (IC), as well as PMUT arrays having high fill factor for fingerprint sensing, are described.

An ultrasonic transducer includes a membrane, a bottom electrode, and a plurality of cavities disposed between the membrane and the bottom electrode, each of the plurality of cavities corresponding to an individual transducer cell. Portions of the bottom electrode corresponding to each individual transducer cell are electrically isolated from one another. Each portion of the bottom electrode corresponds to each individual transducer that cell further includes a first bottom electrode portion and a second bottom electrode portion, the first and second bottom electrode portions electrically isolated from one another.

Various embodiments of the present disclosure are directed towards a semiconductor device. The semiconductor device includes an interconnect structure disposed over a semiconductor substrate. A dielectric structure is disposed over the interconnect structure. A first cavity and a second cavity are disposed in the dielectric structure. A microelectromechanical system (MEMS) substrate is disposed over the dielectric structure, where the MEMS substrate comprises a first movable membrane overlying the first cavity and a second movable membrane overlying the second cavity. A first functional structure overlies the first movable membrane, where the first functional structure comprises a first material having a first chemical composition. A second functional structure overlies the second movable membrane, where the second functional structure is laterally spaced from the first functional structure, and where the second functional structure comprises a second material having a second chemical composition different than the first chemical composition.

A CMOS single chip includes a movable film, at least one support pillar, a base metal layer and a circuit integration. The movable film is disposed on a top layer of the CMOS single chip and has a plurality of through-vias. The support pillar is disposed under the movable film to provide a supporting force of the movable film. The base metal layer is formed under the support pillars and isolated from the support pillars, and faces towards the movable film to form a micro capacitor to sense one of the outside sensing signals. The area of the base metal layer is larger than the area of the movable film. The circuit integration is formed under the base metal layer, or formed under the base metal layer and on the side of the movable film, and connected to the movable film and the base metal layer.

A Microelectromechanical Systems (MEMS) device combining a MEMS layer and a Complementary Metal-Oxide-Semiconductor (CMOS) Integrated Circuit (IC), and its fabrication method is provided. The fabrication method includes: processing the MEMS layer on a first semiconductor substrate, the MEMS layer including one or more movable structures and one or more anchor structures; processing one or more first contacts on the first semiconductor substrate, each first contact being processed into one of the anchor structures and being configured to bias that anchor structure; processing the CMOS IC on a second semiconductor substrate; processing one or more second contacts on the second semiconductor substrate, each second contact being connected to the CMOS IC; and bonding the first semiconductor substrate to the second semiconductor substrate such that each first contact directly contacts one of the second contacts. The method can allow fabricating the MEMS device without vapor HF etching. The method can further enable zero level packaging, fusion bonding, a C-SOI approach, and high-vacuum sealing. An integrated zero level hermetic packaging MEMS device can be realized based on fusion bonding of moisture resistant materials. Further, Cu/dielectric bonding and electrical connections to individual parts of the MEMS device are allowed, in order to apply isolated voltages.