A semiconductor device structure is provided. The semiconductor device structure includes a first substrate including a first face and a second face opposite the first face. A second substrate is bonded to the first face of the first substrate such that the second face of the first substrate faces away from the second substrate. One or more recesses are arranged in the second face of the first substrate and are configured to compensate for thermal expansion or thermal contraction.

A method includes producing a semiconductor wafer. The semiconductor wafer includes a plurality of microelectromechanical system (MEMS) semiconductor chips, wherein the MEMS semiconductor chips have MEMS structures arranged at a first main surface of the semiconductor wafer, a first semiconductor material layer arranged at the first main surface, and a second semiconductor material layer arranged under the first semiconductor material layer, wherein a doping of the first semiconductor material layer is greater than a doping of the second semiconductor material layer. The method further includes removing the first semiconductor material layer in a region between adjacent MEMS semiconductor chips. The method further includes applying a stealth dicing process from the first main surface of the semiconductor wafer and between the adjacent MEMS semiconductor chips.

The method comprises fabricating a semiconductor panel comprising a plurality of semiconductor devices, fabricating a cap panel comprising a plurality of caps, bonding the cap panel onto the semiconductor panel so that each one of the caps covers one or more of the semiconductor devices, and singulating the bonded panels into a plurality of semiconductor modules.

A method for manufacturing a mirror device is a method for manufacturing a mirror device including a structural body that includes a support portion, a movable portion, and a coupling portion, and a mirror layer provided on the movable portion. The method for manufacturing a mirror device includes: a first forming step of forming a plurality of parts on a wafer, each of the plurality of parts corresponding to the structural body; a second forming step of forming the mirror layer on a part of each of the plurality of parts, the part corresponding to the movable portion; a heating step of heating the part of each of the plurality of parts, corresponding to the movable portion, after the first forming step and the second forming step; and a cutting step of cutting the wafer to separate the plurality of parts from one another, after the heating step.

A device chip manufacturing method includes an attaching a wafer to the first surface of a semiconductor ingot, separating the semiconductor ingot into a subject part and a remaining part after attachment, the subject part being attached to the wafer to form a laminated wafer having a front side as an exposed surface of the subject part and a back side as an exposed surface of the wafer, setting a plurality of crossing division lines on the front side of the laminated wafer to thereby define a plurality of separate regions after separation, and next forming a plurality of devices in the respective separate regions, and then dividing the laminated wafer along the division lines after forming the devices, thereby forming the plural device chips including the respective devices.

Disclosed a MEMS assembly and a manufacturing method thereof. The manufacturing method comprises: forming a groove on a sensor chip; forming a bonding pad on a circuit chip; bonding the sensor chip and the circuit chip together to form a bonding assembly; performing a first dicing process at a first position of the sensor chip to penetrate through the sensor chip to the groove; performing a second dicing process at a second position of the sensor chip to penetrate through the sensor chip and the circuit chip, for obtaining an individual MEMS assembly by singulating the bonding assembly, wherein location of the groove corresponds to a position of the bonding pad, and an opening is formed in the sensor chip to expose the bonding pad when the second dicing process is performed. The method uses two dicing process respectively achieving different depths to expose the bonding pad of the sensor chip and singulate the MEMS assembly, respectively, to improve yield and reliability.

A semiconductor device structure is provided. The semiconductor device structure includes a first wafer comprising a first face and a second face opposite the first face and having a plurality of predetermined die areas. A plurality of recesses are disposed in the first face of the first wafer. A first recess of the plurality of recesses extends in a direction substantially parallel to a first edge of at least one of the plurality of predetermined die areas and laterally surrounds the at least one of the plurality of predetermined die areas. A second wafer is bonded to the second face of the first wafer.

A method for forming a semiconductor device structure is provided. The method includes receiving a first wafer having multiple predetermined die areas. The method also includes forming a recess in the first wafer, and the recess extends in a direction substantially parallel to an edge of one of the predetermined die areas. The method further includes receiving a second wafer. In addition, the method includes bonding the first wafer and the second wafer at an elevated temperature after the recess is formed.

A method of manufacturing a physical quantity detection sensor includes forming a stacked structure having a plurality of sensor devices by bonding together a sensor substrate and a different type substrate of a different material from a material of the sensor substrate, the sensor substrate having a plurality of sensor movable portions therein, and dicing the stacked structure using a dicing blade, wherein a groove is provided in one of the sensor substrate and the different type substrate to penetrate the one of the sensor substrate and the different type substrate, the groove having a width larger than a width of the dicing blade, and in at least part of the dicing, the dicing blade is accommodated in the groove and advances without contacting surfaces on left and right sides of the groove.

A method for producing thin MEMS chips on SOI substrate including: providing an SOI substrate having a silicon layer on a front side and having an oxide intermediate layer, producing a layer structure on the front side of the SOI substrate and producing a MEMS structure from this layer structure, capping the MEMS structure and producing a cavity, and etching a back side of the SOI substrate down to the oxide intermediate layer. Also described is a micromechanical component having a substrate, a MEMS layer structure having a MEMS structure in a cavity and a cap element, the MEMS structure and its cavity being enclosed by the substrate underneath and the cap element above, the substrate being made of polycrystalline silicon.