Micro-Electro-Mechanical System (MEMS) structures, methods of manufacture and design structures are disclosed. The method includes forming a Micro-Electro-Mechanical System (MEMS) beam structure by venting both tungsten material and silicon material above and below the MEMS beam to form an upper cavity above the MEMS beam and a lower cavity structure below the MEMS beam.

Micro-Electro-Mechanical System (MEMS) structures, methods of manufacture and design structures are disclosed. The method includes forming a Micro-Electro-Mechanical System (MEMS) beam structure by venting both tungsten material and silicon material above and below the MEMS beam to form an upper cavity above the MEMS beam and a lower cavity structure below the MEMS beam.

Micro-Electro-Mechanical System (MEMS) structures, methods of manufacture and design structures are disclosed. The method includes forming a Micro-Electro-Mechanical System (MEMS) beam structure by venting both tungsten material and silicon material above and below the MEMS beam to form an upper cavity above the MEMS beam and a lower cavity structure below the MEMS beam.

A method for fabricating an electronic device is disclosed. In one example, the method comprises providing a semiconductor wafer, forming a plurality of cavities into the semiconductor wafer, filling a stabilization material into the cavities, fabricating a temporary panel by applying a cap sheet onto the semiconductor wafer, the cap sheet covering the cavities, singulating the temporary panel into a plurality of semiconductor devices, fabricating an embedded wafer by embedding the semiconductor devices in an encapsulant, removing the cap sheet of each one of the semiconductor devices, and singulating the embedded wafer into a plurality of electronic devices.

A method of forming an ultrasonic transducer device includes forming and patterning a film stack over a substrate, the film stack comprising a metal electrode layer and a chemical mechanical polishing (CMP) stop layer formed over the metal electrode layer; forming an insulation layer over the patterned film stack; planarizing the insulation layer to the CMP stop layer; measuring a remaining thickness of the CMP stop layer; and forming a membrane support layer over the patterned film stack, wherein the membrane support layer is formed at thickness dependent upon the measured remaining thickness of the CMP stop layer, such that a combined thickness of the CMP stop layer and the membrane support layer corresponds to a desired transducer cavity depth.

A MEMS device is provided that includes a cap layer and a device layer. The cap layer includes a cap wafer made of electrically insulating material, and the device layer includes at least one seismic element. Moreover, the cap layer includes at least one silicon-filled portion at a first face of the cap layer facing the device layer, and at least one of said at least one silicon-filled portion includes a gap that locally increases distance from the cap layer to the at least one seismic element in the device layer.

The present disclosure provides a CMOS structure, including a substrate, a metallization layer over the substrate, a sensing structure over the metallization layer, and a signal transmitting structure adjacent to the sensing structure. The sensing structure includes an outgassing layer over the metallization layer, a patterned outgassing barrier over the outgassing layer; and an electrode over the patterned outgassing barrier. The signal transmitting structure electrically couples the electrode and the metallization layer.

A method for fabricating packaged semiconductor devices (100) with an open cavity (110a) in panel format; placing (process 201) on an adhesive carrier tape a panel-sized grid of metallic pieces having a flat pad (230) and symmetrically placed vertical pillars (231); attaching (process 202) semiconductor chips (101) with sensor systems face-down onto the tape; laminating (process 203) and thinning (process 204) low CTE insulating material (234) to fill gaps between chips and grid; turning over (process 205) assembly to remove tape; plasma-cleaning assembly front side, sputtering and patterning (process 206) uniform metal layer across assembly and optionally plating (process 209) metal layer to form rerouting traces and extended contact pads for assembly; laminating (process 212) insulating stiffener across panel; opening (process 213) cavities in stiffener to access the sensor system; and singulating (process 214) packaged devices by cutting metallic pieces.

The present disclosure provides a CMOS structure, including a substrate, a metallization layer over the substrate, a sensing structure over the metallization layer, and a signal transmitting structure adjacent to the sensing structure. The sensing structure includes an outgassing layer over the metallization layer, a patterned outgassing barrier over the outgassing layer; and an electrode over the patterned outgassing barrier. The signal transmitting structure electrically couples the electrode and the metallization layer.

The present disclosure provides a CMOS structure, including a substrate, a metallization layer over the substrate, a sensing structure over the metallization layer, and a signal transmitting structure adjacent to the sensing structure. The sensing structure includes an outgassing layer over the metallization layer, a patterned outgassing barrier over the outgassing layer; and an electrode over the patterned outgassing barrier. The signal transmitting structure electrically couples the electrode and the metallization layer.