Abstract: A semiconductive structure includes a first substrate including a first surface and a second surface opposite to the first surface, a second substrate disposed over the first surface and including a first device and a second device, a first capping structure disposed over the second substrate, and including a via extending through the first capping structure to the second device, a first cavity surrounding the first device and defined by the first capping structure and the first substrate, a second cavity surrounding the second device and defined by the first capping structure and the first substrate, and a second capping structure disposed over the first capping structure and covering the via, wherein the second cavity and the via are sealed by the second capping structure.

Abstract: A micro-electro mechanical system (MEMS) device is provided. The MEMS device includes a cap substrate and a MEMS substrate bonded with the cap substrate. The MEMS substrate includes a first movable element and a second movable element. The MEMS device also includes a first closed chamber between the MEMS substrate and the cap substrate, and the first movable element is in the first closed chamber. The MEMS device further includes an outgassing layer in the first closed chamber. In addition, the MEMS device includes a second closed chamber between the MEMS substrate and the cap substrate, and the second movable element is in the second closed chamber.

Abstract: According to an exemplary embodiment of the disclosure, a method of removing a waste part of a substrate is provided. The method includes: using a laser to partially drill the substrate to define the waste part; and applying megasonic vibration to the substrate to remove the waste part from the substrate.

Abstract: An embodiment is MEMS device including a first MEMS die having a first cavity at a first pressure, a second MEMS die having a second cavity at a second pressure, the second pressure being different from the first pressure, and a molding material surrounding the first MEMS die and the second MEMS die, the molding material having a first surface over the first and the second MEMS dies. The device further includes a first set of electrical connectors in the molding material, each of the first set of electrical connectors coupling at least one of the first and the second MEMS dies to the first surface of the molding material, and a second set of electrical connectors over the first surface of the molding material, each of the second set of electrical connectors being coupled to at least one of the first set of electrical connectors.

Abstract: A method of forming a semiconductor device includes bonding a capping wafer and a base wafer to form a wafer package. The base wafer includes a first chip package portion, a second chip package portion, and a third chip package portion. The capping wafer includes a plurality of isolation trenches. Each isolation trench of the plurality of isolation trenches is substantially aligned with a corresponding trench region of one of the first chip package portion, the second chip package portion or the third chip package portion. The method also includes removing a portion of the capping wafer to expose a first chip package portion contact, a second chip package portion contact, and a third chip package portion contact. The method further includes separating the wafer package into a first chip package configured to perform a first operation, a second chip package configured to perform a second operation, and a third chip package configured to perform a third operation.

Abstract: The present disclosure provides flow cells and methods of fabricating flow cells. The method includes combining three portions: a first substrate, a second substrate, and microfluidic channels between the first substrate and the second substrate having walls of a photoresist dry film. Through-holes for inlet and outlet are formed in the first substrate or the second substrate. Patterned capture sites are stamped on the first substrate and the second substrate by a nanoimprint lithography process. In other embodiments, parts of the patterned capture sites are selectively attached to a surface chemistry pattern formed of silicon oxide islands each disposed on an outcrop of a soft bottom layer.

Abstract: A bond free of an anti-stiction layer and bonding method is disclosed. An exemplary method includes forming a first bonding layer; forming an interlayer over the first bonding layer; forming an anti-stiction layer over the interlayer; and forming a liquid from the first bonding layer and interlayer, such that the anti-stiction layer floats over the first bonding layer. A second bonding layer can be bonded to the first bonding layer while the anti-stiction layer floats over the first bonding layer, such that a bond between the first and second bonding layers is free of the anti-stiction layer.

Abstract: A package system includes a first substrate; and a second substrate electrically coupled with the first substrate. The package system further includes a semiconductor material between the first substrate and the second substrate. The semiconductor material includes a pad, and at least one guard ring surrounding the pad and spaced from the pad. The package system further includes a metallic material bonded to the semiconductor material, wherein the metallic material at least partially fills at least one opening in at least one of the first substrate or the second substrate.

Abstract: An embodiment is MEMS device including a first MEMS die having a first cavity at a first pressure, a second MEMS die having a second cavity at a second pressure, the second pressure being different from the first pressure, and a molding material surrounding the first MEMS die and the second MEMS die, the molding material having a first surface over the first and the second MEMS dies. The device further includes a first set of electrical connectors in the molding material, each of the first set of electrical connectors coupling at least one of the first and the second MEMS dies to the first surface of the molding material, and a second set of electrical connectors over the first surface of the molding material, each of the second set of electrical connectors being coupled to at least one of the first set of electrical connectors.

Abstract: The present disclosure provides flow cells and methods of fabricating flow cells. The method includes combining three portions: a first substrate, a second substrate, and microfluidic channels between the first substrate and the second substrate having walls of a photoresist dry film. Through-holes for inlet and outlet are formed in the first substrate or the second substrate. Patterned capture sites are stamped on the first substrate and the second substrate by a nanoimprint lithography process. In other embodiments, parts of the patterned capture sites are selectively attached to a surface chemistry pattern formed of silicon oxide islands each disposed on an outcrop of a soft bottom layer.

Abstract: A semiconductor device includes a moveable element over a substrate, wherein the moveable element is moveable relative to the substrate. The semiconductor device further includes a first anchor portion connected to the substrate; and a second anchor portion connected to the substrate on an opposite side of the moveable element from the first anchor portion. The semiconductor device further includes a first connector configured to connect the moveable element to the first anchor portion. The semiconductor device further includes a second connector configured to connect the moveable element to the second anchor portion. The semiconductor device further includes a conductive wire loop on the moveable element; and a connection wire electrically connected to a first end of the conductive wire loop, wherein the connection wire extends across the first connector to the first anchor portion.

Abstract: In a wafer level chip scale packaging technique for MEMS devices, a deep trench is etched on a scribe line area between two CMOS devices of a CMOS substrate at first. After bonding of the CMOS substrate with a MEMS substrate, the deep trench is opened by thin-down process so that CMOS substrate is singulated while MEMS substrate is not (partial singulation). Electrical test pad on MEMS substrate is exposed and protection material can be filled through the deep trench around bonding layers. After filling the protection material, the wafer is diced to form packaged individual chips with protection from environment outside bonding layer.

Abstract: A device includes a substrate, a routing conductive line over the substrate, a dielectric layer over the routing conductive line, and an etch stop layer over the dielectric layer. A Micro-Electro-Mechanical System (MEMS) device has a portion over the etch stop layer. A contact plug penetrates through the etch stop layer and the dielectric layer. The contact plug connects the portion of the MEMS device to the routing conductive line. An escort ring is disposed over the etch stop layer and under the MEMS device, wherein the escort ring encircles the contact plug.

Abstract: A method of fabricating a device includes forming a moveable plate over a substrate. The method further includes forming an energy harvesting coil in the moveable plate. The method further includes forming at least one connector connecting the movable plate with the substrate, wherein a portion of the energy harvesting coil extends along the at least one connector. The method further includes enclosing the movable plate using a capping wafer.

Abstract: An integrated circuit structure includes a triple-axis accelerometer, which further includes a proof-mass formed of a semiconductor material; a first spring formed of the semiconductor material and connected to the proof-mass, wherein the first spring is configured to allow the proof-mass to move in a first direction in a plane; and a second spring formed of the semiconductor material and connected to the proof-mass. The second spring is configured to allow the proof-mass to move in a second direction in the plane and perpendicular to the first direction. The triple-axis accelerometer further includes a conductive capacitor plate including a portion directly over, and spaced apart from, the proof-mass, wherein the conductive capacitor plate and the proof-mass form a capacitor; an anchor electrode contacting a semiconductor region; and a transition region connecting the anchor electrode and the conductive capacitor plate, wherein the transition region is slanted.

Abstract: MEMS devices and methods of fabrication thereof are described. In one embodiment, the MEMS device includes a bottom alloy layer disposed over a substrate. An inner material layer is disposed on the bottom alloy layer, and a top alloy layer is disposed on the inner material layer, the top and bottom alloy layers including an alloy of at least two metals, wherein the inner material layer includes the alloy and nitrogen. The top alloy layer, the inner material layer, and the bottom alloy layer form a MEMS feature.

Abstract: A method of forming a semiconductor device includes bonding a capping wafer and a base wafer to form a wafer package. The base wafer includes a first chip package portion, a second chip package portion, and a third chip package portion. The capping wafer includes a plurality of isolation trenches. Each isolation trench of the plurality of isolation trenches is substantially aligned with a corresponding trench region of one of the first chip package portion, the second chip package portion or the third chip package portion. The method also includes removing a portion of the capping wafer to expose a first chip package portion contact, a second chip package portion contact, and a third chip package portion contact. The method further includes separating the wafer package into a first chip package configured to perform a first operation, a second chip package configured to perform a second operation, and a third chip package configured to perform a third operation.

Abstract: A package system includes a first substrate; and a second substrate electrically coupled with the first substrate. The package system further includes a semiconductor material between the first substrate and the second substrate. The semiconductor material includes a pad, and at least one guard ring surrounding the pad and spaced from the pad. The package system further includes a metallic material bonded to the semiconductor material, wherein the metallic material at least partially fills at least one opening in at least one of the first substrate or the second substrate.

Abstract: A device includes a substrate, a routing conductive line over the substrate, a dielectric layer over the routing conductive line, and an etch stop layer over the dielectric layer. A Micro-Electro-Mechanical System (MEMS) device has a portion over the etch stop layer. A contact plug penetrates through the etch stop layer and the dielectric layer. The contact plug connects the portion of the MEMS device to the routing conductive line. An escort ring is disposed over the etch stop layer and under the MEMS device, wherein the escort ring encircles the contact plug.

Abstract: A micro-electro mechanical system (MEMS) device is provided. The MEMS device includes a cap substrate and a MEMS substrate bonded with the cap substrate. The MEMS substrate includes a first movable element and a second movable element. The MEMS device also includes a first closed chamber between the MEMS substrate and the cap substrate, and the first movable element is in the first closed chamber. The MEMS device further includes an outgassing layer in the first closed chamber. In addition, the MEMS device includes a second closed chamber between the MEMS substrate and the cap substrate, and the second movable element is in the second closed chamber.