A packaged electronic die having a micro-cavity and a method for forming a packaged electronic die. The packaged electronic die includes a photoresist frame secured to the electronic die and extending completely around the device. The photoresist frame is further secured to a first major surface of a substrate so as to form an enclosure around the device. Encapsulant material extends over the electronic die and around the sides of the electronic die. The encapsulant material is in contact with the first major surface of the substrate around the entire periphery of the electronic die so as to form a seal around the electronic die.

An apparatus and method for wafer-level hermetic packaging of MicroElectroMechanical Systems (MEMS) devices of different shapes and form factors is presented in this disclosure. The method is based on bonding a glass cap wafer with fabricated micro-glassblown “bubble-shaped” structures to the substrate glass/Si wafer. Metal traces fabricated on the substrate wafer serve to transfer signals from the sealed cavity of the bubble to the outside world. Furthermore, the method provides for chip-level packaging of MEMS three dimensional structures. The packaging method utilizes a micro glass-blowing process to create “bubbleshaped” glass lids. This new type of lids is used for vacuum packaging of three dimensional MEMS devices, using a standard commercially available type of package.

A method for producing a microelectromechanical sensor. The microelectromechanical sensor is produced by connecting a cap wafer to a sensor wafer. The cap wafer has a bonding structure for connecting the cap wafer to the sensor wafer. The sensor wafer has a sensor core having a movable structure. The cap wafer has a stop structure for limiting an excursion of the movable structure. The method includes a first step and a second step following the first step, the stop surface of the stop structure being situated at the level of the original surface of the unprocessed cap wafer.

An embodiment method includes forming a first plurality of bond pads on a device substrate, depositing a spacer layer over and extending along sidewalls of the first plurality of bond pads, and etching the spacer layer to remove lateral portions of the spacer layer and form spacers on sidewalls of the first plurality of bond pads. The method further includes bonding a cap substrate including a second plurality of bond pads to the device substrate by bonding the first plurality of bond pads to the second plurality of bond pads.

A pressure sensor includes a silicon substrate which has a diaphragm, a frame-shaped side wall section which is placed on one surface side of the silicon substrate so as to surround the diaphragm in a plan view, a lid section which is placed so as to cover an opening of the side wall section and has a through-hole communicating inside and outside the side wall section, a sealing section which is placed on the lid section and seals the through-hole, and a pressure reference chamber which is defined by the silicon substrate, the side wall section, the lid section, and the sealing section, wherein a surface facing the pressure reference chamber of each of the side wall section and the lid section contains a silicon material.

A capped micromachined device has a movable micromachined structure in a first hermetic chamber and one or more interconnections in a second hermetic chamber that is hermetically isolated from the first hermetic chamber, and a barrier layer on its cap where the cap faces the first hermetic chamber, such that the first hermetic chamber is isolated from outgassing from the cap.

Methods for bonding two wafers are disclosed. In one aspect, a first wafer includes an integrated circuit and the second wafer including a MEMS device. The method comprises depositing a bond pad on a metal on the first wafer and sequentially bonding the first wafer to the second wafer utilizing first and second temperatures. The second wafer is bonded to the bond pad at the first temperature and the bond pad and the metal are bonded at the second temperature. In another aspect, a first wafer including an integrated circuit, the second wafer includes a MEMS device. The method comprises depositing a bond pad on a metal on one of the first wafer and the second wafer and bonding the first wafer to the second wafer at a first temperature via a direct bond interface. The method includes bonding the bond pad to the metal at a second temperature.

A resonance device that includes a MEMS substrate including a resonator, an upper lid that seals a vibration space of the resonator, and a ground portion positioned between the MEMS substrate and the upper lid, the ground portion being extended to an inside of the upper lid and electrically connected to the upper lid.

A multilayer stack comprises a surface wherein a predetermined region is defined for enclosing a device provided on the multilayer stack, the region being encircled by a welding zone defined on the surface, the welding zone being suitable for being welded by a welding radiation beam to a capping structure. It also comprises a first layer embedded within the multilayer stack, including at least one embedded component suitable for being functionally connected to the device provided on the multilayer stack. It furthermore comprises at least a second layer over the first layer comprising a shielding structure positioned between the at least one component of the first layer and the welding zone defined on the surface, the shielding structure being adapted to limit the welding depth of the welding radiation beam provided on the welding zone.

A method includes: providing a first substrate on which a plurality of first semiconductor devices is formed; providing a second substrate on which a plurality of second semiconductor devices is formed; and coupling the first and second substrates by contacting respective dummy pads of the first and second substrates, wherein at least one of the dummy pads of the first and second substrates comprises plural peaks and valleys.