According to an example aspect of the present invention, there is provided a wafer level package for a device, the package comprising: a first substrate and a second substrate, a sealing structure comprising a seal ring and a bonding layer between the first substrate and the second substrate, and a lateral electrical connection line on a surface of the first substrate, which lateral electrical connection line extends through the seal ring for creating an electrical connection between the device inside the package and an electrical circuit outside the package.

A MEMS device comprises an electro mechanical element in a sealed chamber containing a gas comprising a reactive gas selected to react with any contaminants that may be present or formed on the operating surfaces of the device in a manner to maximize the electrical conductivity of the surfaces during operation of the device. The MEMS device may comprise a MEMS switch having electrical contacts as the operating surfaces. The reactive gas may comprise hydrogen or an azane, optionally mixed with an inert gas, or any combination of the gases. The corresponding process provides a means to substantially reduce or eliminate contaminants present or formed on the operating surfaces of MEMS devices in a manner to maximize the electrical conductivity of the surfaces during operation of the devices.

An inertial sensor 1 includes: a base body; a lid body facing the base body; a functional element disposed in a cavity between the base body and the lid body and including a semiconductor layer; an adhesive layer disposed in a peripheral region surrounding the cavity and adhering the base body and the lid body to each other; and a sealer configured to seal a hole which communicates the cavity with an outside and which is disposed in the peripheral region. The sealer is provided in contact with the lid body and the base body, and includes a material of the lid body and a material of the adhesive layer.

Various embodiments of the present disclosure are directed towards a method for manufacturing an integrated chip, the method comprises forming an interconnect structure over a semiconductor substrate. An upper dielectric layer is formed over the interconnect structure. An outgas layer is formed within the upper dielectric layer. The outgas layer comprises a first material that is amorphous. A microelectromechanical systems (MEMS) substrate is formed over the interconnect structure. The MEMS substrate comprises a moveable structure directly over the outgas layer.

Embodiments for a packaged semiconductor device and methods of making are provided herein, where a packaged semiconductor device includes a package body having a recess in which a pressure sensor is exposed; a polymeric gel within the recess that vertically and laterally surrounds the pressure sensor; and a protection layer including a plurality of beads embedded within a top region of the polymeric gel.

A method for manufacturing a MEMS device includes disposing at least one bonding portion having a smaller bonding area in a region where an airtight chamber will be formed, and disposing a metal getter on a bonding surface of the bonding portion. According to this structure, when substrates are bonded to define the airtight chamber, the metal getter is squeezed out of the bonding position due to the larger bonding pressure of the bonding portion with a smaller bonding area. Then, the metal getter is activated to absorb the moisture in the airtight chamber. According to the above process, no additional procedure is needed to remove the moisture in the airtight chamber. A MEMS device manufactured by the above manufacturing method is also disclosed.

In described examples, a bondline structure is arranged along a periphery of a cavity. The bondline structure extends from a first substrate and is configured to bond with an interposer arranged on a second substrate. A diffusion barrier is arranged on the first substrate for contacting the interposer. The diffusion barrier is arranged to impede a contaminant against migrating from the bondline structure and entering the cavity.

A method for transferring a semiconductor layer from a donor substrate to a receiver substrate having an open cavity includes forming an embrittlement plane in the donor substrate, making, by bringing the donor substrate and the receiver substrate into contact, a packaging in which the cavity is buried, and separating the packaging by fracturing along the embrittlement plane. The separating causes a transfer of the semiconductor layer to the receiver substrate and a sealing of the cavity by the semiconductor layer. The method also includes, prior to making the packaging, implanting diffusing species into the donor substrate or into the receiver substrate and, subsequently to making the packaging and prior to separating the packaging, diffusing the species into the cavity.

Systems and methods are provided that provide a getter in a micromechanical system. In some embodiments, a microelectromechanical system (MEMS) is bonded to a substrate. The MEMS and the substrate have a first cavity and a second cavity therebetween. A first getter is provided on the substrate in the first cavity and integrated with an electrode. A second getter is provided in the first cavity over a passivation layer on the substrate. In some embodiments, the first cavity is a gyroscope cavity, and the second cavity is an accelerometer cavity.

Microelectromechanical system (MEMS) packages and methods of making thereof. A MEMS package includes at least one MEMS device disposed on a base substrate and a lid disposed on the base substrate. The lid is configured to enclose the at least one MEMS device. The lid includes a body portion configured to be coupled to the base substrate, a ceiling portion and a membrane. The ceiling portion, the body portion and the ceiling portion form a cavity in which the at least one MEMS device is enclosed. The membrane is configured to be in contact with the ceiling portion. The membrane is formed from a filtering fabric and is configured to substantially block one or more of liquids and contaminants from passing into the cavity.