A Microelectromechanical Systems (MEMS) structure with integrated heater is disclosed. The MEMS structure with integrated heater comprises a first substrate with cavities, bonded to a second substrate, forming a plurality of sealed enclosures of at least two types. Each of the plurality of sealed enclosures is defined by the first substrate, the second substrate, and a seal-ring material, where the first enclosure type further includes at least one of a gettering element to decrease cavity pressure in the first enclosure type or an outgassing element to increase cavity pressure in the first enclosure type when activated. The first enclosure type further comprises at least one heater integrated into the first substrate adjacent to the gettering element or the outgassing element to adjust the temperature of the gettering element or the outgassing element thereby providing heating to the gettering element or the outgassing element.

Various embodiments of the present disclosure are directed towards an integrated chip including a capping structure over a device substrate. The device substrate includes a first microelectromechanical systems (MEMS) device and a second MEMS device laterally offset from the first MEMS device. The capping structure includes a first cavity overlying the first MEMS device and a second cavity overlying the second MEMS device. The first cavity has a first gas pressure and the second cavity has a second gas pressure different from the first cavity. An outgas layer abutting the first cavity. The outgas layer includes an outgas material having an outgas species. The outgas material is amorphous.

A microelectromechanical system (MEMS) structure and method of forming the MEMS device, including forming a first metallization structure over a complementary metal-oxide-semiconductor (CMOS) wafer, where the first metallization structure includes a first sacrificial oxide layer and a first metal contact pad. A second metallization structure is formed over a MEMS wafer, where the second metallization structure includes a second sacrificial oxide layer and a second metal contact pad. The first metallization structure and second metallization structure are then bonded together. After the first metallization structure and second metallization structure are bonded together, patterning and etching the MEMS wafer to form a MEMS element over the second sacrificial oxide layer. After the MEMS element is formed, removing the first sacrificial oxide layer and second sacrificial oxide layer to allow the MEMS element to move freely about an axis.

A microphone assembly comprises a substrate. An acoustic transducer is disposed on the substrate, the acoustic transducer configured to generate an electrical signal responsive to acoustic activity. An integrated circuit is disposed on the substrate and electrically coupled to the acoustic transducer, the integrated circuit configured to generate an output signal indicative of the acoustic activity based on the electrical signal from the acoustic transducer. An enclosure is coupled to the substrate and defines an internal volume between the enclosure and the substrate, the enclosure having an outer surface exposed to an outside environment of the microphone assembly, and an inner surface adjacent the internal volume. An insulating layer is disposed on the inner surface of the enclosure. The insulating layer comprises a fluoropolymer.

A method is provided for producing a hermetically sealed housing having a semiconductor component. The method comprises introducing a housing having a housing body and a housing cover into a process chamber. The housing cover closes off a cavity of the housing body and is attached in a gas-tight manner to the housing body. At least one opening is formed in the housing. At least one semiconductor component is arranged in the cavity. The method furthermore comprises generating a vacuum in the cavity by evacuating the process chamber, and also generating a predetermined gas atmosphere in the cavity and the process chamber. The method moreover comprises applying sealing material to the at least one opening while the predetermined gas atmosphere prevails in the process chamber.

A microelectronic device package includes a host material and a gettering material. The microelectronic device package also includes a polymeric component between the host material and the gettering material. The polymeric component substantially encapsulates the gettering material. The microelectronic device package further includes a fluorochemical lubricant. The polymeric component serves to prevent a reaction between the fluorochemical lubricant and the gettering material. Alternatively, the fluorochemical lubricant may be encapsulated by a polymeric component and may be released upon an increase in temperature during or after a packaging step.

A package structure that includes a pair of substrates arranged to oppose each other so as to form an internal space; a bonding portion sealing the pair of substrates; an element is sealed in the internal space and surrounded by the pair of substrates; an adsorption layer within the internal space and opposing at least one substrate of the pair of substrates, the adsorption layer constructed to adsorbs at least hydrogen; and a diffusion-inhibiting layer between the at least one substrate and the adsorption layer, and in which hydrogen is more difficult to diffuse compared with in the at least one substrate.

A MEMS chip package is provided with a removable cover to allow non-destructive testing. The MEMS package has a container (with walls and a bottom) and a cover. The cover has a glass pane, and is secured to the MEMS package with an elastomeric gasket mounted between the walls of the MEMS package and the cover. A number of attachment mechanisms secure the cover to the MEMS package.

The present disclosure provides a micro electro mechanical system (MEMS) structure, including a device substrate having a first region and a second region different from the first region, a capping substrate bonded over the device substrate, a first cavity in the first region and between the device substrate and capping substrate, wherein the first cavity has a first cavity pressure, a second cavity in the second region and between the device substrate and capping substrate, wherein the second cavity has a second cavity pressure lower than the first cavity pressure, an outgassing material, wherein the outgassing material includes a top surface and a sidewall exposed to the first cavity, the outgassing material is free from being in direct contact with the capping substrate, wherein the outgassing material includes a trench, and a passivation layer disposed over the device substrate, and is in direct contact with the outgassing material.

A MEMS element within a semiconductor device is enclosed within a cavity bounded at least in part by hydrogen-permeable material. A hydrogen barrier is formed within the semiconductor device to block propagation of hydrogen into the cavity via the hydrogen-permeable material.