A production method for a double-membrane MEMS component includes: providing a layer arrangement on a carrier substrate, wherein the layer arrangement comprises a first membrane structure, a sacrificial material layer adjoining the first membrane structure, and a counterelectrode structure in the sacrificial material layer and at a distance from the first membrane structure, wherein at least one through opening is formed in the sacrificial material layer as far as the first membrane structure; forming a filling material structure in the at least one through opening by applying a first filling material layer on the wall region of the at least one through opening; applying a second membrane structure on the layer arrangement with the sacrificial material; and removing the sacrificial material from an intermediate region to expose the filling material structure in the intermediate region.

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.

A semiconductor structure is provided. The semiconductor structure includes a substrate, a plurality of vias, a signal transmitting portion, a heater and a sensing material. The plurality of vias penetrates the substrate, wherein each of the plurality of vias includes a conductive or semiconductive portion surrounded by an oxide layer. The signal transmitting portion is disposed in the substrate, wherein adjacent vias of the plurality of vias surrounds the signal transmitting portion. The heater is electrically connected to the signal transmitting portion, and the sensing material is disposed over the heater and electrically connected to the substrate. A method of manufacturing a semiconductor structure is also provided.

A manufacturing method for multiple MEMS sound transducers includes manufacturing a reconstructed wafer, separating multiple chips from the wafer, and encapsulating the chips in a molding material. A piezoelectric element of the particular chips is exposed to become deflectable along a stroke axis. The reconstructed wafer is connected to multiple diaphragms associated with the particular chips, wherein the diaphragms are each connected to the associated piezoelectric element so that the diaphragms are each deflectable together with the at least one associated piezoelectric element along the stroke axis. MEMS sound transducers, each of which including at least one of the chips and one of the diaphragms, are isolated. A MEMS sound transducer, which has been manufactured using the aforementioned manufacturing method, is also disclosed.

In accordance with one exemplary embodiment, a production method for a double-membrane MEMS component comprises the following steps: providing a layer arrangement on a carrier substrate, wherein the layer arrangement has a first and second membrane structure spaced apart from one another and a counterelectrode structure arranged therebetween, wherein a sacrificial material is arranged in an intermediate region between the counterelectrode structure and the first and second membrane structures respectively spaced apart therefrom, and wherein the first membrane structure has an opening structure to the intermediate region with the sacrificial material and partly removing the sacrificial material from the intermediate region in order to obtain a mechanical connection structure comprising the sacrificial material between the first and second membrane structures, which mechanical connection structure is mechanically coupled between the first and second membrane structures and is mechanically decoupled from the counterelectrode structure.

In accordance with one exemplary embodiment, a production method for a double-membrane MEMS component comprises the following steps: providing a layer arrangement on a carrier substrate, wherein the layer arrangement has a first and second membrane structure spaced apart from one another and a counterelectrode structure arranged therebetween, wherein a sacrificial material is arranged in an intermediate region between the counterelectrode structure and the first and second membrane structures respectively spaced apart therefrom, and wherein the first membrane structure has an opening structure to the intermediate region with the sacrificial material and partly removing the sacrificial material from the intermediate region in order to obtain a mechanical connection structure comprising the sacrificial material between the first and second membrane structures, which mechanical connection structure is mechanically coupled between the first and second membrane structures and is mechanically decoupled from the counterelectrode structure.

A micro-electro-mechanical device, comprising a monolithic body of semiconductor material accommodating a first buried cavity; a sensitive region facing the first buried cavity; a second cavity facing the first buried cavity; a decoupling trench extending from the monolithic body and separating the sensitive region from a peripheral portion of the monolithic body; a cap die, forming an ASIC, bonded to and facing the first face of the monolithic body; and a first gap between the cap die and the monolithic body. The device also comprises at least one spacer element between the monolithic body and the cap die; at least one stopper element between the monolithic body and the cap die; and a second gap between the stopper element and one between the monolithic body and the cap die. The second gap is smaller than the first gap.

Micromachined ultrasonic transducers integrated with complementary metal oxide semiconductor (CMOS) substrates are described, as well as methods of fabricating such devices. Fabrication may involve two separate wafer bonding steps. Wafer bonding may be used to fabricate sealed cavities in a substrate. Wafer bonding may also be used to bond the substrate to another substrate, such as a CMOS wafer. At least the second wafer bonding may be performed at a low temperature.

A production method for a double-membrane MEMS component includes: providing a layer arrangement on a carrier substrate, wherein the layer arrangement comprises a first membrane structure, a sacrificial material layer adjoining the first membrane structure, and a counterelectrode structure in the sacrificial material layer and at a distance from the first membrane structure, wherein at least one through opening is formed in the sacrificial material layer as far as the first membrane structure; forming a filling material structure in the at least one through opening by applying a first filling material layer on the wall region of the at least one through opening; applying a second membrane structure on the layer arrangement with the sacrificial material; and removing the sacrificial material from an intermediate region to expose the filling material structure in the intermediate region.

Disclosed is a method of fabricating a MEMS membrane structure. The method comprises: forming a silicon oxide film dam structure on a silicon substrate; depositing an adhesive layer and then forming a sacrificial layer; depositing a surface protective film on the sacrificial layer; etching the surface protective film and the sacrificial layer, thus forming trenches of first to third rows on the silicon oxide film dam structure; depositing a support film inside of the trenches of first to third rows and on the surface protective film of the sacrificial layer, thus forming a membrane; and removing the sacrificial layer disposed inside the support film deposited inside of the trench of first row, thus forming an empty space.