The present invention relates to a micromechanical component (1), comprising a substrate (2), on which at least one layer sequence (3) is situated, which includes at least one micromechanical functional element, and on which at least one layer sequence (4) is situated that is able to act as at least one macroelectronic, passive component.

A semiconductor device composed of a capacitive humidity sensor comprised of a moisture-sensitive polymer layer electrografted to an electrically conductive metal layer situated on an CMOS substrate or a combined MEMS and CMOS substrate, and exposed within an opening through a passivation layer, packages composed of the encapsulated device, and methods of forming the capacitive humidity sensor within the semiconductor device, are provided.

The application relates to integrated MEMS transducers comprising a MEMS transducer structure formed of a plurality of transducer layers and at least one circuit component formed from a plurality of circuitry (CMOS) layers. The integrated MEMS transducer further comprises a conductive enclosure that is integral to the transducer layers and circuitry layers. The at least one circuit component is inside the conductive enclosure whilst the MEMS transducer structure is outside the enclosure.

A CMOS-based process for manufacturing a semiconductor gas sensor includes the steps of: I) providing a semi-product, II) etching a substrate to remove a portion of the substrate and a portion of a first insulation layer so as to form a gas-sensing cavity, thereby to expose at least one sensing electrode; and III) depositing a gas-sensitive layer to cover the at least one sensing electrode.

Provided are a MEMS pressure sensor and a method for forming the MEMS pressure sensor. The method includes: preparing a first substrate, where the first substrate includes a first surface and a second surface opposite to the first surface; preparing a second substrate, where the second substrate includes a third surface and a fourth surface opposite to the third surface, the second substrate includes a pressure sensing region; bonding the first surface of the first substrate and the third surface of the second substrate with each other; forming a cavity between the first substrate and the pressure sensing region of the second substrate; removing the second base to form a fifth surface opposite to the third surface of the second substrate; and forming a first conductive plug passing through the second substrate from the side of the fifth surface of the second substrate to the at least one conductive layer.

MEMS devices and methods for forming the same are provided. A first metal interconnect structure is formed on a first semiconductor substrate to connect to a CMOS control circuit in the first semiconductor substrate. A bonding layer having a cavity is formed on the first metal interconnect structure, and then bonded with a second semiconductor substrate. A conductive plug passes through a first region of the second semiconductor substrate, through the bonding layer, and on the first metal interconnect structure. A second metal interconnect structure includes a first end formed on the first region of the second semiconductor substrate, and a second end connected to the conductive plug. Through-holes are disposed through a second region of the second semiconductor substrate and through a top portion of the bonded layer that is on the cavity to leave a movable electrode to form the MEMS device.

The present invention discloses a micro-electro-mechanical system silicon on insulator (MEMS SOI) pressure sensor and a method for preparing the same. The pressure sensor includes a bulk silicon layer, a buried oxide layer, a substrate, a varistor, a passivation layer, and an electrode layer. The varistor is obtained by means of photolithography and ion implantation on a device layer of an SOI wafer. The passivation layer is SiO.sub.2 formed by means of annealing treatment on the SOI wafer. An annealing atmosphere is one of pure O.sub.2, a gas mixture of O.sub.2/H.sub.2O, a gas mixture of O.sub.2/NO, a gas mixture of O.sub.2/HCl, and a gas mixture of O.sub.2/CHF.sub.3. By means of the annealing treatment, the damage to a surface of the buried oxide layer as a result of over-etching during formation of the varistor by means of photolithography is eliminated and the unstability of the sensor caused by body and interface defects of the passivation layer and trapped charges thereof is resolved. A trench is formed at the buried oxide layer and the bulk silicon layer directly below the varistor, which helps overcome defects as a result of doped impurities entering the buried oxide layer below the varistor, and helps improve the sensitivity of the sensor.

A sensor device includes a semiconductor chip. The semiconductor chip has a sensing region sensitive to mechanical loading. A pillar is mechanically coupled to the sensing region.

A method of fabricating a semiconductor device comprises forming a dielectric layer above a substrate, the dielectric layer including a fixed dielectric portion and a proof mass portion, forming a source region and a drain region in the substrate, forming a gate electrode in the proof mass portion, and releasing the proof mass portion, such that the proof mass portion is movable with respect to the fixed dielectric portion and the gate electrode is movable with the proof mass portion relative to the source region and the drain region.

The invention relates to antenna apparatus comprising: an antenna, a signal conductor and one or more RF MEMS switches, the antenna being conductively connected to the signal conductor, the MEMS switches and at least a portion of the signal conductor being supported by a crystalline MEMS substrate; and a capping substrate comprising a capping portion, wherein an enclosed volume is formed around the said MEMS switches between the capping portion and at least a portion of the crystalline MEMS substrate, and wherein the capping substrate comprises the said antenna.