A method for fabricating a MEMS device includes depositing and patterning a first sacrificial layer onto a silicon substrate, the first sacrificial layer being partially removed leaving a first remaining oxide. Further, the method includes depositing a conductive structure layer onto the silicon substrate, the conductive structure layer making physical contact with at least a portion of the silicon substrate. Further, a second sacrificial layer is formed on top of the conductive structure layer. Patterning and etching of the silicon substrate is performed stopping at the second sacrificial layer. Additionally, the MEMS substrate is bonded to a CMOS wafer, the CMOS wafer having formed thereupon a metal layer. An electrical connection is formed between the MEMS substrate and the metal layer.

A micromechanical device having a substrate wafer, a functional layer situated above it which has a mobile micromechanical structure, and a cap situated on top thereof, having a first cavity, which is formed at least by the substrate wafer and the cap and which includes the micromechanical structure. The micromechanical device has a fixed part and a mobile part, which are movably connected to each other with at least one spring element, and the first cavity is situated in the mobile part. Also described is a method for producing the micromechanical device.

A method for bonding two substrates is described, comprising providing a first and a second silicon substrate, providing a raised feature on at least one of the first and the second silicon substrate, forming a layer of gold on the first and the second silicon substrates, and pressing the first substrate against the second substrate, to form a thermocompression bond around the raised feature. The high initial pressure caused by the raised feature on the opposing surface provides for a hermetic bond without fracture of the raised feature, while the complete embedding of the raised feature into the opposing surface allows for the two bonding planes to come into contact. This large contact area provides for high strength.

An antenna having radio-frequency (RF) resonators and methods for fabricating the same are described. In one embodiment, the antenna comprises a physical antenna aperture having an array of antenna elements, where the array of antenna elements includes a plurality of radio-frequency (RF) resonators, with each RF resonator of the plurality of RF resonators having an RF radiating element with a microelectromchanical systems (MEMS) device.

Provided herein is a method including forming a cavity in a first side of a first silicon wafer. An oxide layer is formed on the first side and in the cavity. The first side of the first silicon wafer is bonded to a first side of a second silicon wafer, and a gap control structure is deposited on a second side of the second silicon wafer. A MEMS structure is formed in the second silicon wafer. The second side of the second silicon wafer is eutecticly bonded to the third silicon wafer, and the eutectic bonding includes pressing the second silicon wafer to the third silicon wafer.

A semiconductor structure includes a first substrate including a cavity extended into the first substrate, a device disposed within the cavity, a first dielectric layer disposed over the first substrate and a first conductive structure surrounded by the first dielectric layer, and a second substrate including a second dielectric layer disposed over the second substrate and a second conductive structure surrounded by the second dielectric layer, wherein the first conductive structure is bonded with the second conductive structure and the first dielectric layer is bonded with the second dielectric layer to seal the cavity.

A method for encapsulating a microelectronic device, arranged on a support substrate, with an encapsulation cover includes, inter alia, the following sequence of steps: a) providing a support substrate on which a microelectronic device is arranged, b) depositing a bonding layer on the first face of the substrate, around the microelectronic device, c) positioning an encapsulation cover on the bonding layer in such a way as to encapsulate the microelectronic device, d) thinning the second main face of the support substrate and the second main face of the encapsulation cover by chemical etching.

Representative implementations of techniques and devices provide seals for sealing the joints of bonded microelectronic devices as well as bonded and sealed microelectronic assemblies. Seals are disposed at joined surfaces of stacked dies and wafers to seal the joined surfaces. The seals may be disposed at an exterior periphery of the bonded microelectronic devices or disposed within the periphery using the various techniques.

A micro-electro-mechanical system (MEMS) package structure and a method for fabricating the MEMS package structure. The MEMS package structure includes a MEMS die (200) and a device wafer (100). A control unit and an interconnection structure (300) are formed in the device wafer (100), and a first contact pad (410) and an input-output connecting member (420) are formed on a first bonding surface (100a) of the device wafer (100). The MEMS die (200) is coupled to the first bonding surface (100a) through a bonding layer (500). The MEMS die (200) includes a closed micro-cavity (220) and a second contact pad (220). The first contact pad (410) is electrically connected to a corresponding second contact pad (220). An opening (510) that exposes the input-output connecting member (420) is formed in the bonding layer (500). The MEMS package structure allows electrical interconnection between the MEMS die (200) and the device wafer (100) with a reduced package size, compared to those produced by existing integration techniques. In addition, function integration ability of the package structure is improved by integrating a plurality of MEMS dies of the same or different structures and functions on the same device wafer.

In an electro-optic device, a chip provided with a mirror and a drive element adapted to drive the mirror, a cover having a light-transmitting property and adapted to cover the mirror in a planar view, and a spacer located between the cover and the chip are disposed on an interconnection board. Further, a boundary between the cover and the spacer, a boundary between the chip and the spacer, and a part of the interconnection board are covered with an inorganic film such as an aluminum oxide film. The inorganic film also covers a part of a chip-side terminal and an internal terminal, and a conductive member.