A thermal airflow sensor includes a semiconductor device, a protective film a bonding wire, and a resin. The resin covers over a part of the semiconductor device so that the bonding wire is covered with the resin and the region including a thin-wall portion is exposed. The protective film is not covered with the resin and has an outer peripheral edge located outside the thin-wall portion.

A method of manufacturing a MEMS chip includes: providing a silicon substrate layer, the silicon substrate layer comprising a front surface configured to perform a MEMS process and a rear surface opposite to the front surface; growing a first oxidation layer mainly made of SiO.sub.2 on the rear surface of the silicon substrate layer by performing a thermal oxidation process; and depositing a first thin film layer mainly made of silicon nitride on the first oxidation layer by performing a low pressure chemical vapor deposition process.

A semiconductor manufacturing method includes providing a wafer. A layer is formed over a surface of the wafer where the layer is able to form a eutectic layer with a conductive element. The layer is partially removed so as to form a plurality of mesas. The wafer is bonded to a substrate through the plurality of mesas. The substrate is thinned down to a thickness so as to be less than a predetermined value.

A method of removing a reinforcement ring from a wafer is described. The method includes forming a ring-shaped recess in a first surface of the wafer and separating the reinforcement ring from an inner region of the wafer along the ring-shaped recess.

A method for manufacturing a MEMS device is disclosed. Moreover a MEMS device and a module including a MEMS device are disclosed. An embodiment includes a method for manufacturing MEMS devices includes forming a MEMS stack over a first main surface of a substrate, forming a polymer layer over a second main surface of the substrate and forming a first opening in the polymer layer and the substrate such that the first opening abuts the MEMS stack.

A manufacturing method of a micro electro mechanical system (MEMS) device includes forming a buffer protection layer on a semiconductor structure, wherein the semiconductor structure includes a wafer, a MEMS membrane, and an isolation layer between the wafer and the MEMS membrane, and the buffer protection layer is located in a slit of the MEMS membrane and on a surface of the MEMS membrane facing away from the isolation layer; etching the wafer to form a cavity such that a portion of the isolation layer is exposed though the cavity; etching the portion of the isolation layer; and removing the buffer protection layer.

A coating for protecting a wafer from moisture and debris due to dicing, singulating, or handling the wafer is provided. A semiconductor sensor device comprises a wafer having a surface and at least one trench feature and the protective coating covering the trench feature. The trench feature comprises a plurality of walls and the walls are covered with the protective coating, wherein the walls of the trench feature are formed as a portion of the semiconductor sensor device. The semiconductor sensor device further comprises a patterned mask formed on the wafer before the trench feature is formed, wherein the protective coating is formed directly to the trench feature and the patterned mask. The semiconductor sensor device is selected from a group consisting of a MEMS die, a sensor die, a sensor circuit die, a circuit die, a pressure die, an accelerometer, a gyroscope, a microphone, a speaker, a transducer, an optical sensor, a gas sensor, a bolometer, a giant magnetoresistive sensor (GMR), a tunnel magnetoresistive (TMR) sensor, an environmental sensor, and a temperature sensor.

A method comprises forming an etch stop layer, a first titanium layer, a magnetic core, a second titanium layer, and patterning the first and second titanium layers. The etch stop layer is formed above a substrate. The first titanium layer is formed on the etch stop layer. The magnetic core is formed on the first titanium layer. The second titanium layer has a first portion encapsulating the magnetic core with the first titanium layer, and a second portion interfacing with the first titanium layer beyond the magnetic core. The patterning of the first and second titanium layers includes forming a mask over a magnetic core region and etching the first and second titanium layers exposed by the mask using a titanium etchant and a titanium oxide etchant.

A thermal airflow sensor includes a semiconductor device, a protective film a bonding wire, and a resin. The resin covers over a part of the semiconductor device so that the bonding wire is covered with the resin and the region including a thin-wall portion is exposed. The protective film is not covered with the resin and has an outer peripheral edge located outside the thin-wall portion.

The present disclosure provides a method for forming micro-electro-mechanical-system (MEMS) devices. The method includes providing a plurality of wafers; bonding a front surface of at least a first wafer onto a front surface of a second wafer; trimming an edge of and thinning the at least first wafer after the at least first wafer is bonded onto the second wafer; and bonding a first supporting plate onto a front surface of a third wafer. The method further includes thinning a back surface of the third wafer and forming alignment marks on a thinned back surface of the third wafer; bonding a second supporting plate onto the thinned back surface of the third wafer according to the alignment marks; and removing the first supporting plate and bonding the at least first wafer onto the third wafer according to the alignment marks to form a stack structure.