A method for fabricating a Microelectromechanical System (MEMS) resonator includes providing a dielectric substrate defining a resonator and depositing a conductive coating having a resistivity of approximately 1 to 50 -cm on that substrate by Atomic Layer Deposition (ALD). A resonator fabricated according to this process includes a dielectric substrate defining a resonator and a conductive coating having a resistivity of approximately 1 to 50 -cm for electrically coupling the resonator to electronics. Another method for fabricating a MEMS resonator includes providing a dielectric substrate defining a resonator, depositing an aluminum oxide film on that substrate by ALD, and depositing a noble metal film on the aluminum oxide film, also by ALD.

The invention provides a micromechanical device comprising a support structure and a deflecting element connected to the support structure, wherein the deflecting element comprises at least one deformable member adapted to deform extensionally, flexurally or torsionally with respect to a deformation axis for allowing deflection of the deflecting element with respect to the support structure. Further, there are means for statically deflecting the deflecting element or detecting the magnitude of static deflection of the deflecting element. According to the invention, the deformable member is made of silicon doped with an n-type doping agent to a doping concentration of at least 1.1*10.sup.20 cm.sup.3. The invention allows for manufacturing micromechanical devices whose mechanical operation is not affected by prevailing temperature conditions.

The application relates to MEMS transducers comprising at least one support structure for connecting a backplate structure of the transducer with an underlying substrate. A strengthening portion is provided in the region of the support structure.

Three-dimensional micro devices usable as electromagnetic and magnetomechanical energy converters, as micromagnetic motors or generators, and methods for their production. The three-dimensional micro devices exhibit high efficiency even at dimensions on the microscale and below, and the method for production, as well as mass production, is simple and economical. Moreover, the three-dimensional micro devices at least include one three-dimensional device produced using roll-up technology. This three-dimensional device includes all functional and structural components for full functionality. At least one functional or structural component is an element that is at least partially freely movable at least partially within a surrounding element and is arranged such that it can be rotated at least around one of its axes.

In accordance with an embodiment, a MEMS structure is produced on a front side of a substrate. A decoupling structure which has recesses is produced in the substrate, which decoupling structure decouples a first region from a second region of the substrate in terms of stresses. In a rear side, situated opposite the front side, of the substrate, a first cavity is produced by means of a first etching process and a second cavity is produced by means of a second etching process. The first cavity and the second cavity are produced such that the second cavity encompasses the first cavity and such that the second cavity adjoins a base region of the MEMS structure and a base region of the decoupling structure.

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.

A MicroElectroMechanical (MEMS) device includes a suspended electrode structure anchored to a substrate, the MEMS device having a MEMS resonance mode, and a Tuned Mass Damping (TMD) structure, wherein a portion of the suspended electrode structure forms a TMD structure having a TMD spring element and a TMD mass element, for providing a TMD resonance mode counteracting the MEMS resonance mode.

The present invention provides a micro evaporator, an oscillator integrated micro evaporator structure and a frequency correction method thereof. The micro evaporator comprises a micro evaporation platform, anchor points, supporting beams and metal electrodes, wherein one surface of the micro evaporation platform is an evaporation surface; the anchor points are located on two sides of the micro evaporation platform and have a certain distance to the micro evaporation platform; the supporting beams are located between the micro evaporation platform and the anchor points, one end of each supporting beam is connected with the micro evaporation platform and the other end is connected with the anchor point; the size of each supporting beam satisfies the following relation: T=P(L/2kbh)+T.sub.a; and the metal electrodes are located on first surfaces of the anchor points.

A MEMS microphone having a backplate, a spring, and a membrane. In one embodiment, the membrane is supported in an approximate center of the membrane via a support. The support is connected to the approximate center of the membrane and an approximate center of the backplate. The membrane is connected to a spring that provides an electrical connection. The membrane may be electrically biased via the electrical connection. One or more overtravel stops are fixed to the backplate and pass through an aperture of the membrane. The overtravel stops are configured to prevent movement of the membrane in a radial direction opposite to the backplate. The membrane includes a stress gradient, a corrugation, or another structure that sets or determines a stiffness of the membrane.

A physical quantity sensor includes a driven section and a drive spring that supports the driven section so that the driven section is displaceable in a first direction. The drive spring has a serpentine shape and includes a plurality of spring structures extending in a second direction that intersects a first direction. At least one of the spring structures has a thin section that is thinner in a third direction that intersects the first and second directions than the other portions of the drive spring.