A semiconductor structure is provided. The semiconductor structure includes a first substrate, a semiconductor layer, a second substrate, and a eutectic sealing structure. The semiconductor layer is over the first substrate. The semiconductor layer has a cavity at least partially through the semiconductor layer. The second substrate is over the semiconductor layer. The second substrate has a through hole. The eutectic sealing structure is on the second substrate and covers the through hole. The eutectic sealing structure comprises a first metal layer and a second metal layer eutectically bonded on the first metal layer. A method for manufacturing a semiconductor structure is also provided.

A package for encapsulating a functional area against an environment includes a base substrate and a cover substrate, the base substrate together with the cover substrate defining at least part of the package or defining the package, and furthermore including the at least one functional area provided in the package, and a blocking way for reducing permeation between the environment and the functional area. The package may include at least one laser bonding line, and the substrates of the package can be hermetically joined to one another by the at least one laser bonding line, and the laser bonding line has a height (HL) perpendicular to its bonding plane.

A micromechanical component for a sensor device, including a substrate, at least one first counter-electrode, at least one first electrode adjustably situated on a side of the at least one first counter-electrode facing away from the substrate, and a capacitor sealing structure, which seals gas-tight an interior volume, including the at least one first counter-electrode present therein and the at least one first electrode present therein. The at least one first counter-electrode is fastened directly or indirectly to a frame structure fastened directly or indirectly to the substrate, and the frame structure framing a cavity, and the at least one first counter-electrode at least partially spanning the cavity in such a way that at least one gas is transferable between the cavity and the interior volume via at least one opening formed at and/or in the at least one first counter-electrode.

A method is disclosed. In one example, the method includes bonding a first panel of a first material to a base panel in a first gas atmosphere, wherein multiple hermetically sealed first cavities encapsulating gas of the first gas atmosphere are formed between the first panel and the base panel. The method further includes bonding a second panel of a second material to at least one of the base panel and the first panel, wherein multiple second cavities are formed between the second panel and the at least one of the base panel and the first panel.

A process for manufacturing a combined microelectromechanical device includes forming, in a die of semiconductor material, at least a first and a second microelectromechanical structure, performing a first bonding phase to bond a cap to the die via a bonding region or adhesive to define at least a first and a second cavity at the first and, respectively, second microelectromechanical structures, the cavities being at a controlled pressure, forming an access channel through the cap in fluidic communication with the first cavity to control the pressure value inside the first cavity in a distinct manner with respect to a respective pressure value inside the second cavity, and performing a second bonding phase, after which the bonding region deforms to hermetically close the first cavity with respect to the access channel.

A method of fabricating and packaging an ohmic micro-electro-mechanical system (MEMS) switch device may comprise constructing the switch device on an insulating substrate. The switch device may have contacts that consist of a platinum-group metal. The method may further comprise forming an oxidized layer of the platinum-group metal on an outer surface of each of the one or more contacts. The method may further comprise bonding an insulating cap to the insulating substrate, to hermetically seal the switch device. The bonding may occur in an atmosphere that has a proportion of oxygen within a range of 0.5% to 30%, such that, after the switch device has been hermetically sealed within the sealed cavity, an atmosphere within the sealed cavity has a proportion of oxygen within the range of 0.5% to 30%. The platinum-group metal may be ruthenium, and the oxidized layer of the platinum-group metal may be ruthenium dioxide.

An optical scanning device includes a reflector as a MEMS mirror having a reflection surface of a metal film, a support body, a drive beam, and a drive unit. The support body is disposed to be spaced from the reflector so as to surround the reflector. The drive beam connects the reflector and the support body. A first protection film is formed all over opposite side surfaces including side wall surfaces of a second semiconductor layer, as well as an upper surface and a lower surface, in the drive beam. As the first protection film, a silicon oxide film, a silicon nitride film, an alumina film, or a titania film is formed by an atomic layer deposition method.

A method is disclosed. In one example, the method includes bonding a first panel of a first material to a base panel in a first gas atmosphere, wherein multiple hermetically sealed first cavities encapsulating gas of the first gas atmosphere are formed between the first panel and the base panel. The method further includes bonding a second panel of a second material to at least one of the base panel and the first panel, wherein multiple second cavities are formed between the second panel and the at least one of the base panel and the first panel.

A method of fabricating and packaging an ohmic micro-electro-mechanical system (MEMS) switch device may comprise constructing the switch device on an insulating substrate. The switch device may have contacts that consist of a platinum-group metal. The method may further comprise forming an oxidized layer of the platinum-group metal on an outer surface of each of the one or more contacts. The method may further comprise bonding an insulating cap to the insulating substrate, to hermetically seal the switch device. The bonding may occur in an atmosphere that has a proportion of oxygen within a range of 0.5% to 30%, such that, after the switch device has been hermetically sealed within the sealed cavity, an atmosphere within the sealed cavity has a proportion of oxygen within the range of 0.5% to 30%. The platinum-group metal may be ruthenium, and the oxidized layer of the platinum-group metal may be ruthenium dioxide.

A micro-electromechanical system (MEMS) device includes a moveable element within a cavity. The MEMS device also includes a first layer over the cavity, the first layer having a first hole and a second hole. The first hole has a first diameter. The second hole has a second diameter. The second diameter is larger than the first diameter, and the second hole is farther from the moveable element than the first hole. The first hole is sealed with a first dielectric material. The second hole is sealed with a second dielectric material. The cavity filled with a gas at a pressure of at least approximately 10 torr.