A sensor component having a MEMS sensor and an ASIC for one sensor function each. A base element, a wall element in the form of a frame and a cover together enclose a cavity of a housing. The MEMS sensor is mounted inside the cavity on the base element of the housing. The ASIC has an active sensor surface and is mounted on or under the cover or is embedded in the cover. Electrical external contacts for the MEMS sensor and ASIC are provided on an external surface of the housing. The cavity has at least one opening or bushing.

A MEMS device is formed by applying a lower polymer film to top surfaces of a common substrate containing a plurality of MEMS devices, and patterning the lower polymer film to form a headspace wall surrounding components of each MEMS device. Subsequently an upper polymer dry film is applied to top surfaces of the headspace walls and patterned to form headspace caps which isolate the components of each MEMS device. Subsequently, the MEMS devices are singulated to provide separate MEMS devices.

A microelectronic system including hydrogen barriers and copper pillars for wafer level packaging and method of fabricating the same are provided. Generally, the method includes: forming an insulating hydrogen barrier over a surface of a first chip; exposing at least a portion of an electrical contact electrically coupled to a component in the first chip by removing a portion of the insulating hydrogen barrier, the component including a material susceptible to degradation by hydrogen; forming a conducting hydrogen barrier over at least the exposed portion of the electrical contact; and forming a copper pillar over the conducting hydrogen barrier. In one embodiment, the material susceptible to degradation is lead zirconate titanate (PZT) and the microelectronic systems device is a ferroelectric random access memory including a ferroelectric capacitor with a PZT ferroelectric layer. Other embodiments are also disclosed.

Production of a device for connecting a nano-object to an external electrical system (SEE) including: a first chip provided with conducting areas (8a, 8b) and a first nano-object (50) connected to the conducting areas, the first chip being assembled on a support (70) such that the first nano-object is arranged facing an upper face of the support, the device being further provided with first connection elements (80a, 80b) capable of being connected to the external electrical system and arranged on and in contact with the first conducting areas (8a, 8b), the first connection elements being formed on the side of the upper face of the support (70) and being accessible from the side of the upper face of the support.

A functional element includes a substrate which is provided with a concave section; a stationary section connected to a wall section that defines the concave section of the substrate; an elastic section which extends from the stationary section and is capable of stretching and contracting in a first axis direction; a movable body connected to the elastic section; a movable electrode section which extends from the movable body. The concave section includes a cutout section which is provided on the wall section. The stationary section includes an overlap section which is spaced with the substrate, and overlaps the concave section when seen in a plan view. At least a portion of the overlap section overlaps the cutout section when seen in the plan view, and the elastic section extends from the overlap section.

The cap wafer for a MEMS device includes multiple electrically isolated electrodes that can be bonded and electrically connected to separate electrical contacts on a MEMS device wafer. The electrically isolated electrodes can be used for any of a variety of functions, such as for apply a force to a movable MEMS structure on the MEMS device wafer (e.g., for driving resonance of the movable MEMS structure or for adjusting a resonance or sense mode of the movable MEMS structure) or for sensing motion of a movable MEMS structure on the MEMS device wafer. Since the electrodes are electrically isolated, different electrodes may be used for different functions.

A MEMS sensor package comprises a MEMS die that includes a substrate having a sensor formed thereon and a cap layer coupled to the substrate. The cap layer has a cavity overlying a substrate region at which the sensor resides. A port extends between the cavity and a side wall of the MEMS die and enables admittance of fluid into the cavity. Fabrication methodology entails providing a substrate structure having sensors formed thereon, providing a cap layer structure having inwardly extending cavities, and forming a channel between pairs of the cavities. The cap layer structure is coupled with the substrate structure and each channel is interposed between a pair of cavities. A singulation process produces a pair of sensor packages, each having a port formed by splitting the channel, where the port is exposed during singulation and extends between its respective cavity and side wall of the sensor package.

The present disclosure provides a semiconductor device. The semiconductor device includes a first device and a second device disposed adjacent to the first device; a conductive pillar disposed adjacent to the first device or the second device; a molding surrounding the first device, the second device and the conductive pillar; and a redistribution layer (RDL) over the first device, the second device, the molding and the conductive pillar, wherein the RDL electrically connects the first device to the second device and includes an opening penetrating the RDL and exposing a sensing area over the first device.

A device for sensing characteristics of the environment and/or various media such as pressure is provided. The assembled device may include a sensor module having gel encapsulation, metal covers, and plastic overmoulding. Associated methods for assembling devices having overmoulded pressure sensor modules with gel encapsulation and metal covers are provided.

In examples, a micro-electromechanical (MEMS) device comprises a substrate and a semiconductor die coupled to the substrate and including circuitry formed therein. The semiconductor die also includes a bond pad coupled to the circuitry. The MEMS device includes a structure extending away from the semiconductor die and having four sides, with the structure comprising a corrodible material. The MEMS device includes an epoxy contacting outer surfaces of the four sides of the structure and over the corrodible material.