The present publication discloses a micromechanical structure including at least one active element, the micromechanical structure comprising a substrate, at least one layer formed on the substrate forming the at least part of the at least one active element, mechanical contact areas through which the micromechanical structure can be connected to other structures like printed circuit boards and like. In accordance with the invention the micromechanical structure includes weakenings like trenches around the mechanical contact areas for eliminating the thermal mismatch between the active element of the micromechanical structure and the other structures.

The present disclosure relates to a MEMS vibrator or the like that has excellent chemical resistance and an excellent mechanical strength and that is easily thinned. The present disclosure is a MEMS vibrator comprising: a vibrating film including a graphite film; and a silicon member supporting the vibrating film, the graphite film having a thickness of 50 nm or more and less than 20 m, and the graphite film having a Young's modulus along a graphite film plane direction of 700 GPa or more.

A semiconductor device may include a stress decoupling structure to at least partially decouple a first region of the semiconductor device and a second region of the semiconductor device. The stress decoupling structure may include a set of trenches that are substantially perpendicular to a main surface of the semiconductor device. The first region may include a micro-electro-mechanical (MEMS) structure. The semiconductor device may include a sealing element to at least partially seal openings of the stress decoupling structure.

A MEMS device includes a lower substrate having a resonator, an upper substrate disposed to oppose an upper electrode of the resonator, a bonding layer sealing an internal space between the lower substrate and the upper substrate, and wiring layers that contain the same metal material as the bonding layer. Moreover, a rare gas content of each of the wiring layers is less than 110.sup.20 (atoms/cm.sup.3).

A method is described for closing off a micromechanical device by laser melting, having the steps: (A) providing a micromechanical device having an access channel that has a collar at an external opening; (B) closing off the external opening of the access channel by laser irradiation of the collar, the collar being at least partly melted and the external opening being closed with melt made of a material of the collar. Also described is a micromechanical device having a laser melt closure, in particular produced by the method according to the present invention, the micromechanical device having an access channel that has a collar at an external opening, the external opening of the access channel being closed by a melt closure made of a material of the collar.

A packaged micro-electro-mechanical system (MEMS) device (100) comprises a circuitry chip (101) attached to the pad (110) of a substrate with leads (111), and a MEMS (150) vertically attached to the chip surface by a layer (140) of low modulus silicone compound. On the chip surface, the MEMS device is surrounded by a polyimide ring (130) with a surface phobic to silicone compounds. A dome-shaped glob (160) of cured low modulus silicone material covers the MEMS and the MEMS terminal bonding wire spans (180); the glob is restricted to the chip surface area inside the polyimide ring and has a surface non-adhesive to epoxy-based molding compounds. A package (190) of polymeric molding compound encapsulates the vertical assembly of the glob embedding the MEMS, the circuitry chip, and portions of the substrate; the molding compound is non-adhering to the glob surface yet adhering to all other surfaces.

The present publication discloses a micromechanical structure including at least one active element, the micromechanical structure comprising a substrate, at least one layer formed on the substrate forming the at least part of the at least one active element, mechanical contact areas through which the micromechanical structure can be connected to other structures like printed circuit boards and like. In accordance with the invention the micromechanical structure includes weakenings like trenches around the mechanical contact areas for eliminating the thermal mismatch between the active element of the micromechanical structure and the other structures.

Examples provided herein are associated with a molded lead frame of a sensor package. An example sensor package may include a molded lead frame that includes an opening in the molded lead frame, wherein the opening extends from a mount-side of the molded lead frame to a chip-side of the molded lead frame, wherein the chip-side of the molded lead frame is opposite the mount-side; and a sensor mounted to the chip-side of the molded lead frame.

A method for manufacturing a micromechanical component having a disengaged pressure sensor device includes: configuring an electrically conductive sacrificial element in or on a first outer surface of a first substrate; applying a second substrate on or upon the outer surface of the first substrate over the sacrificial element; configuring a pressure sensor device by anodic etching of the second substrate; configuring in the second substrate at least one trench that extends to the sacrificial element; and at least partly removing the sacrificial element in order to disengage the pressure sensor device.

The microphone and pressure sensor package comprises a carrier (1) with an opening (16), a microphone device (20) including a diaphragm (21) and a perforated back plate (22) arranged above the opening (16), an ASIC device (6), and a cover (9) forming a cavity (17) between the carrier (1) and the cover (9). The ASIC device (6) and the microphone device (20) are arranged in the cavity (17). A sensor element (7) provided for a pressure sensor is integrated in the ASIC device (6). The pressure outside the cavity (17) is transferred to the sensor element (7) through the opening (16), the diaphragm (21), and the back plate (22).