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 method for manufacturing a micromechanical device includes providing a silicon substrate having a front side and a rear side, where a first normal of the front side deviates by a first angle from the <111> direction of the silicon substrate; forming in the front side first and second trenches that are spaced apart from and essentially parallel to each other, with the first and second trenches extending along a direction of the deviation; forming on the front side a first etching mask that covers the front side except for a first opening area between the first and second trenches; and anisotropically etching the front side using the etching mask, thereby forming in the opening area an oblique surface having a second angle to the first normal, which approximately corresponds to the first angle.

Systems and methods that protect CMOS layers from exposure to a release chemical are provided. The release chemical is utilized to release a micro-electro-mechanical (MEMS) device integrated with the CMOS wafer. Sidewalls of passivation openings created in a complementary metal-oxide-semiconductor (CMOS) wafer expose a dielectric layer of the CMOS wafer that can be damaged on contact with the release chemical. In one aspect, to protect the CMOS wafer and prevent exposure of the dielectric layer, the sidewalls of the passivation openings can be covered with a metal barrier layer that is resistant to the release chemical. Additionally or optionally, an insulating barrier layer can be deposited on the surface of the CMOS wafer to protect a passivation layer from exposure to the release chemical.

A semiconductor device comprises a structured metal layer. The structured metal layer lies above a semiconductor substrate. In addition, a thickness of the structured metal layer is more than 100 nm. Furthermore, the semiconductor device comprises a covering layer. The covering layer lies adjacent to at least one part of a front side of the structured metal layer and adjacent to a side wall of the structured metal layer. In addition, the covering layer comprises amorphous silicon carbide.

A method for fabricating an integrated MEMS-CMOS device. The method can include providing a substrate member having a surface region and forming a CMOS IC layer having at least one CMOS device overlying the surface region. A bottom isolation layer can be formed overlying the CMOS IC layer and a shielding layer and a top isolation layer can be formed overlying a portion of bottom isolation layer. The bottom isolation layer can include an isolation region between the top isolation layer and the shielding layer. A MEMS layer overlying the top isolation layer, the shielding layer, and the bottom isolation layer, and can be etched to form at least one MEMS structure having at least one movable structure and at least one anchored structure.

There is provided a method for forming a composite cavity and a composite cavity formed using the method. The method comprises the following steps: providing a silicon substrate (101); forming an oxide layer on the front side thereof; patterning the oxide layer to form one or more grooves (103), the position of the groove (103) corresponding to the position of small cavity (109) to be formed; providing a bonding wafer (104), which is bonded to the patterned oxide layer to form one or more closed micro-cavity structures (105) between the silicon substrate (101) and the bonding wafer (104); forming a protective film (106) over the bonding wafer (104) and forming a masking layer (107) on the back side of the silicon substrate (101); patterning the masking layer (107), the pattern of the masking layer (107) corresponding to the position of a large cavity (108) to be formed; using the masking layer (107) as a mask, etching the silicon substrate (101) from the back side until the oxide layer at the front side thereof to form the large cavity (108) in the silicon substrate (101); and using the masking layer (107) and the oxide layer as a mask, etching the bonding wafer (104) from the back side through the silicon substrate (101) until the protective film (106) thereover to form one or more small cavities (109) in the bonding wafer (104). The uniformity of thickness of the semiconductor medium layer where the small cavity (109) in the composite cavity is located is well controlled by the present invention.

A method and system for preparing a semiconductor wafer are disclosed. In a first aspect, the method comprises providing a passivation layer over a patterned top metal on the semiconductor wafer, etching the passivation layer to open a bond pad in the semiconductor wafer using a first mask, depositing a protection layer on the semiconductor wafer, patterning the protective layer using a second mask, and etching the passivation layer to open other electrodes in the semiconductor wafer using a third mask. The system comprises a MEMS device that further comprises a first substrate and a second substrate bonded to the first substrate, wherein the second substrate is prepared by the aforementioned steps of the method.

A manufacturing method for a microelectronic component assembly and a microelectronic component assembly. The manufacturing method includes providing a sensor having a first surface and a second surface opposite to the first surface, as well as at least one lateral surface, at least sections of the first surface including a detection surface. In a subsequent step, a sacrificial material is deposited onto the first surface of the sensor, at least some regions of the detection surface being covered by the sacrificial material, and the sacrificial material extending to the lateral surface of the sensor. A carrier having a mounting surface is then provided. Subsequently, the sensor is connected electrically on the carrier, the first surface of the sensor and the mounting surface of the carrier facing each other at a distance. Afterwards, the sacrificial material is removed, the detection surface becoming at least partially free of the sacrificial material.

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 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.