The detection structure for a MEMS accelerometer is formed by a substrate; a first movable mass and a second movable mass which extend at a distance from each other, suspended on the substrate and which are configured to undergo a movement, with respect to the substrate, in response to an acceleration. The detection structure also has a first movable electrode integral with the first movable mass; a second movable electrode integral with the second movable mass; a first fixed electrode integral with the substrate and configured to form, with the first movable electrode, a first variable capacitor; and a second fixed electrode integral with the substrate and configured to form, with the second movable electrode, a second variable capacitor. The detection structure has an insulation region, of electrically insulating material, which is suspended on the substrate and extends between the first movable mass and the second movable mass.

A capacitive microelectromechanical device is provided. The capacitive microelectromechanical device includes a semiconductor substrate, a support structure, an electrode element, a spring element, and a seismic mass. The support structure, for example, a pole, suspension or a post, is fixedly connected to the semiconductor substrate, which may comprise silicon. The electrode element is fixedly connected to the support structure. Moreover, the seismic mass is connected over the spring element to the support structure so that the seismic mass is displaceable, deflectable or movable with respect to the electrode element. Moreover, the seismic mass and the electrode element form a capacitor having a capacitance which depends on a displacement between the seismic mass and the electrode element.

A NEMS device structure and a method for forming the same are provided. The NEMS device structure includes a first dielectric layer formed over a substrate, and a first conductive layer formed in the first dielectric layer. The NEMS device structure includes a second dielectric layer formed over the first dielectric layer, and a first supporting electrode a second supporting electrode and a beam structure formed in the second dielectric layer. The beam structure is formed between the first supporting electrode and the second supporting electrode, and the beam structure has a T-shaped structure. The NEMS device structure includes a first through hole formed between the first supporting electrode and the beam structure, and a second through hole formed between the second supporting electrode and the beam structure.

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 microelectromechanical systems (MEMS) device, includes forming a cavity in a bulk semiconductor substrate; defining a movably suspended mass in the bulk semiconductor substrate by one or more trenches extending from a main surface area of the bulk semiconductor substrate to the cavity; arranging a cap structure on the main surface area of the bulk semiconductor substrate; and forming a capacitive structure. Forming the capacitive structure includes arranging a first electrode structure on the movably suspended mass; and providing a second electrode structure at the cap structure such that the first electrode structure and the second electrode structure are spaced apart in a direction perpendicular to the main surface area of the bulk semiconductor substrate.

A method of fabricating a MEMS structure includes providing a substrate comprising a logic element region and a MEMS region. Next, a logic element is formed within the logic element region. A nitrogen-containing material layer is formed to cover the logic element region and the MEMS region conformally. Then, part of the nitrogen-containing material layer within the MEMS region is removed to form at least one shrinking region. Subsequently, a dielectric layer is formed to cover the logic element region and MEMS region, and the dielectric layer fills in the shrinking region. After that, the dielectric layer is etched to form at least one releasing hole, wherein the shrinking region surrounds the releasing hole. Finally, the substrate is etched to form a chamber.

A semiconductor element includes a processed substrate arrangement including a processed semiconductor substrate and a metallization layer arrangement on a main surface of the processed semiconductor substrate. The semiconductor element further includes a passivation layer arranged at an outer border of the processed substrate arrangement.

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.

Methods and apparatus for proving a sensor assembly. Embodiments can include employing a circuit assembly having a first layer bonded to a second layer with an oxide layer, depositing bonding oxide on the second layer of the circuit assembly, and thinning the first layer of the circuit assembly after depositing the bonding oxide. A coating can be applied over at least a portion of the first layer of the circuit assembly after annealing the circuit assembly. After polishing the bonding oxide on the second surface of the second layer of the circuit assembly, a shim can be secured to the bonding oxide on the second surface of the second layer of the circuit assembly to reduce bow of the assembly. Embodiments can provide a sensor useful in focal plane arrays.

A micromechanical system (MEMS) device package comprising a substrate and a first enclosure including a first cavity, coupled to the substrate. Wherein a transverse dimension of the first cavity relative to the substrate is configured to reduce undesirable acoustic modes within the first cavity and the first cavity comprises an acoustic port. A MEMS device is located inside the first cavity and an Application Specific Integrated Circuit (ASIC) is communicatively coupled to the MEMS device and located outside the first cavity.