A package includes a base structure, which has an electrically isolating material and/or an electrically conductive contact structure, an electronic component, which is embedded in the base structure or is arranged on the base structure, a microelectromechanical system (MEMS) component, and a cover structure, which is mounted on the base structure for at least partially covering the MEMS component.

A MEMS device includes a dual membrane, an electrode, and an interconnecting structure. The dual membrane has a top membrane and a bottom membrane. The bottom membrane is positioned between the top membrane and the electrode and the interconnecting structure defines a spacing between the top membrane and the bottom membrane.

A semiconductor integrated device, comprising: a package defining an internal space and having an acoustic-access opening in acoustic communication with an environment external to the package; a MEMS acoustic transducer, housed in the internal space and provided with an acoustic chamber facing the acoustic-access opening; and a filtering module, which is designed to inhibit passage of contaminating particles having dimensions larger than a filtering dimension and is set between the MEMS acoustic transducer and the acoustic-access opening. The filtering module defines at least one direct acoustic path between the acoustic-access opening and the acoustic chamber.

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 method includes tab dicing a region of a tab region disposed between a first die and a second die. The tab region structurally connects the first die to the second die each including a MEMS device eutecticly bonded to a CMOS device. The tab region includes a handle wafer layer disposed over a fusion bond oxide layer that is disposed on an ACT layer. The tab region is positioned above a CMOS tab region that with the first and second die form a cavity therein. The tab dicing cuts through the handle wafer layer and leaves a portion of the fusion bond oxide layer underneath the handle wafer layer to form an oxide tether within the tab region. The oxide tether maintains the tab region in place and above the CMOS tab region. Subsequent to the tab dicing the first region, the tab region is removed.

The present disclosure relates to a method of forming an integrated chip structure. The method includes forming a plurality of interconnect layers within a dielectric structure over a substrate. A dielectric layer arranged along a top of the dielectric structure is patterned to define a via hole exposing an uppermost one of the plurality of interconnect layers. An extension via is formed within the via hole and one or more conductive materials are formed over the dielectric layer and the extension via. The one or more conductive materials are patterned to define a sensing electrode over and electrically coupled to the extension via. A microelectromechanical systems (MEMS) substrate is bonded to the substrate. The MEMs substrate is vertically separated from the sensing electrode.

A method of fabricating a semiconductor structure includes: providing a first wafer; providing a second wafer having a first surface and a second surface opposite to the first surface; contacting the first surface of the second wafer with the first wafer; and forming a plurality of scribe lines on the second surface of the second wafer, wherein the formation of the plurality of scribe lines includes removing portions of the second wafer from the second surface towards the first surface to form a third surface between the first surface and the second surface, and the plurality of scribe lines protrudes from the third surface of the second wafer.

A micromechanical sensor device and a corresponding manufacturing method are described. The micromechanical sensor device is fitted with a substrate including a front side and a rear side; a micromechanical sensor chip including a sensor area attached to the front side of the substrate; and a capping unit attached to the front side of the substrate, which is formed at least partially by an ASIC chip. The capping unit surrounds the micromechanical sensor chip in such a way that a cavity closed toward the front side of the substrate is formed between the sensor area of the micromechanical sensor chip and the ASIC chip. A mold package is formed above the capping unit.

A method of fabricating a semiconductor structure includes: providing a first wafer; providing a second wafer having a first surface and a second surface opposite to the first surface; contacting the first surface of the second wafer with the first wafer; and forming a plurality of scribe lines on the second surface of the second wafer, wherein the formation of the plurality of scribe lines includes removing portions of the second wafer from the second surface towards the first surface to form a third surface between the first surface and the second surface, and the plurality of scribe lines protrudes from the third surface of the second wafer.

A semiconductor device includes a first substrate; a dielectric layer disposed over the first substrate and a conductive layer disposed in the dielectric layer; a second substrate bonded to the dielectric layer, wherein the second substrate has a first surface facing the first substrate and a second surface opposite to the first substrate; a connecting structure penetrating the second substrate and a portion of the dielectric layer and electrically coupled to the conductive layer; a vent hole penetrating the second substrate from the second surface to the first surface; a first buffer layer between the connecting structure and the dielectric layer and between the connecting structure and the second substrate; and a second buffer layer covering sidewalls of the vent hole and exposed through the first surface of the second substrate. The first buffer layer and the second buffer layer include a same material and a same thickness.