A MEMS device comprising: a semiconductor body defining a main cavity and forming an anchorage structure; and a first deformable structure having a first end and a second end that are opposite to one another along a first axis, the first deformable structure being fixed to the anchorage structure via the first end so as to be suspended over the main cavity. The second end is configured to oscillate, with respect to the anchorage structure, along a second axis. The first deformable structure comprises a main body having a first outer surface and a second outer surface, and a piezoelectric structure, which extends over the first outer surface. The main body comprises a bottom portion and a top portion that delimit along the second axis a first buried cavity aligned with the piezoelectric structure along the second axis, wherein a maximum thickness of the top portion of the main body along the second axis is smaller than a minimum thickness of the bottom portion of the main body along the second axis.

A method for manufacturing a semiconductor device includes providing a semiconductor structure including a first electrode layer, forming a sacrificial layer on the first electrode layer, the sacrificial layer including a recess having a pointed bottom defining a depth, forming a second electrode layer on the sacrificial layer, the second electrode layer including a first opening exposing the recess, and forming a support layer filling the recess, the first opening, and on the second electrode layer. A portion of the support layer filling the recess forms a stopper having a height equal to the depth of the recess. The method also includes forming a second opening extending through the support layer and the second electrode layer and exposing a surface of the sacrificial layer, and removing a portion of the sacrificial layer to form a cavity.

A method of forming a Micro-Electro-Mechanical System (MEMS) includes forming a lower electrode on a first insulator layer within a cavity of the MEMS. The method further includes forming an upper electrode over another insulator material on top of the lower electrode which is at least partially in contact with the lower electrode. The forming of the lower electrode and the upper electrode includes adjusting a metal volume of the lower electrode and the upper electrode to modify beam bending.

An exemplary method includes forming a sacrificial layer along sidewalls of an array of trenches that are indented into a substrate, depositing a fill layer over the sacrificial layer, and then creating an array of gaps between the fill layer and the substrate by removing the sacrificial layer along the sidewalls of the trenches, while maintaining a structural connection between the substrate and the fill layer at the floors of the trenches. The method further includes covering the substrate, the fill layer, and the gaps with a cap layer that seal fluid-tight against the substrate and the fill layer. The method further includes indenting a first reservoir and a second reservoir through the cap layer, and into the substrate and the fill layer, across the lengths of the array of gaps, so that the array of gaps connects the first reservoir in fluid communication with the second reservoir.

A semiconductor structure includes a first device and a second device. The first device includes a plate including a plurality of apertures; a membrane disposed opposite to the plate and including a plurality of corrugations, and a conductive plug extending through the plate and the membrane. The second device includes a substrate and a bond pad disposed over the substrate, wherein the conductive plug is bonded with the bond pad to integrate the first device with the second device, and the plate includes a semiconductive member and a tensile member, and the semiconductive member is disposed within the tensile member.

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.

A MEMS microphone includes a substrate having a cylindrical cavity, a back plate disposed over the substrate and having a plurality of acoustic holes defined therethrough, a diaphragm disposed between the substrate and the back plate, the diaphragm spaced apart from the substrate and the back plate, covering the cavity to form an air gap between the back plate, and being configured to generate a displacement with responding to an acoustic pressure and an anchor extending from an end portion of the diaphragm and extending along a circumference of the diaphragm, and the anchor including a lower surface in contact with an upper surface of the substrate to support the diaphragm, and a connecting portion, which is connected to the diaphragm, presenting a stepped cross section. Thus, the MEMS microphone may have improved flexibility and improved total harmonic distortion.

A MEMS microphone includes a substrate having a cavity, a back plate being disposed over the substrate and having a plurality of acoustic holes, a diaphragm disposed between the substrate and the back plate, the diaphragm being spaced apart from the substrate and the back plate, covering the cavity to form an air gap between the back plate, and being configured to generate a displacement in response to an acoustic pressure and a plurality of anchors extending from an end portion of the diaphragm to be integrally formed with the diaphragm, the anchors being arranged along a circumference of the diaphragm to be spaced apart from each other, and having lower surfaces making contact with an upper surface of the substrate to support the diaphragm. Thus, the MEMS microphone may have improved rigidity and flexibility.

In a microelectromechanical component according to the invention, at least one microelectromechanical element (5), electrical contacting elements (3) and an insulation layer (2.2) and thereon a sacrificial layer (2.1) formed with silicon dioxide are formed on a surface of a CMOS circuit substrate (1) and the microelectromechanical element (5) is arranged freely movably in at least a degree of freedom. At the outer edge of the microelectromechanical component, extending radially around all the elements of the CMOS circuit, a gas- and/or fluid-tight closed layer (4) which is resistant to hydrofluoric acid and is formed with silicon, germanium or aluminum oxide is formed on the surface of the CMOS circuit substrate (1).

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.