The invention relates to a method for producing optical components, wherein a first contact surface is formed by bringing a deformation element into contact with a carrier; and a second contact surface is formed by applying a functional element to the deformation element; said second contact surface at least partially overlapping the first contact surface, so that a deformation zone is formed by the area of the deformation element that lies between the overlapping areas of the two contact surfaces, wherein at least one portion of the deformation zone is heated and deformed in such a way that the functional element is deflected, in particular, shifts and/or tilts, and the functional element is joined with the deformation element during the process step of applying the functional element to the deformation element and/or during the process step of heating and deforming the deformation zone.

A method of forming a multiple layer, hybrid interposer structure includes forming a plurality of first openings through a substrate, the substrate comprising a heat spreading material; forming a first metal material within the plurality of first openings and on top and bottom surfaces of the substrate; patterning the first metal material; forming a dielectric layer over the patterned first metal material; forming a plurality of second openings within the dielectric layer to expose portions of the patterned first metal material on the top and bottom surfaces of the substrate; filling the plurality of second openings with a second metal material, in contact with the exposed portions of the patterned first metal material; forming a third metal material on the top and bottom surfaces of the substrate, the third metal material in contact with the second metal material and the dielectric layer; and patterning the third metal material.

A MEMS device formed in a first semiconductor substrate is sealed using a second semiconductor substrate. To achieve this, an Aluminum Germanium structure is formed above the first substrate, and a polysilicon layer is formed above the second substrate. The first substrate is covered with the second substrate so as to cause the polysilicon layer to contact the Aluminum Germanium structure. Thereafter, eutectic bonding is performed between the first and second substrates so as to cause the Aluminum Germanium structure to melt and form an AlGeSi sealant thereby to seal the MEMS device. Optionally, the Germanium Aluminum structure includes, in part, a layer of Germanium overlaying a layer of Aluminum.

A MEMS device formed in a first semiconductor substrate is sealed using a second semiconductor substrate. To achieve this, an Aluminum Germanium structure is formed above the first substrate, and a polysilicon layer is formed above the second substrate. The first substrate is covered with the second substrate so as to cause the polysilicon layer to contact the Aluminum Germanium structure. Thereafter, eutectic bonding is performed between the first and second substrates so as to cause the Aluminum Germanium structure to melt and form an AlGeSi sealant thereby to seal the MEMS device. Optionally, the Germanium Aluminum structure includes, in part, a layer of Germanium overlaying a layer of Aluminum.

The invention relates to a method for producing optical components, wherein a first contact surface is formed by bringing a deformation element into contact with a carrier; and a second contact surface is formed by applying a functional element to the deformation element; said second contact surface at least partially overlapping the first contact surface, so that a deformation zone is formed by the area of the deformation element that lies between the overlapping areas of the two contact surfaces, wherein at least one portion of the deformation zone is heated and deformed in such a way that the functional element is deflected, in particular, shifts and/or tilts, and the functional element is joined with the deformation element during the process step of applying the functional element to the deformation element and/or during the process step of heating and deforming the deformation zone.

The MEMS device has: a sensor body having a functional structure configured to transduce a physical or chemical quantity into a corresponding electrical quantity; and a cap bonded to the sensor body and having a first cavity overlying the functional structure. The cap has a supporting portion and a cover portion that form the first cavity. The supporting portion is bonded to the sensor body. The cover portion is bonded to the supporting portion and has an inner wall delimiting on a side the first cavity and facing the functional structure. The MEMS device further has a first coating that extends within the first cavity on the inner wall of the cover portion.

A MEMS device formed in a first semiconductor substrate is sealed using a second semiconductor substrate. To achieve this, an Aluminum Germanium structure is formed above the first substrate, and a polysilicon layer is formed above the second substrate. The first substrate is covered with the second substrate so as to cause the polysilicon layer to contact the Aluminum Germanium structure. Thereafter, eutectic bonding is performed between the first and second substrates so as to cause the Aluminum Germanium structure to melt and form an AlGeSi sealant thereby to seal the MEMS device. Optionally, the Germanium Aluminum structure includes, in part, a layer of Germanium overlaying a layer of Aluminum.

An optical electronics device includes first, second and third wafers. The first wafer has a semiconductor substrate with a dielectric layer on a side of the semiconductor substrate. The second wafer has a transparent substrate with an anti-reflective coating on a side of the transparent substrate. The first wafer is bonded to the second wafer at a silicon dioxide layer between the semiconductor substrate and the anti-reflective coating. The first and second wafers include a cavity extending from the dielectric layer through the semiconductor substrate and through the silicon dioxide layer to the anti-reflective coating. The third wafer includes micromechanical elements. The third wafer is bonded to the dielectric layer, and the micromechanical elements are contained within the cavity.

For an optical electronic device and method that forms cavities through an interposer wafer after bonding the interposer wafer to a window wafer, the cavities are etched into the bonded interposer/window wafer pair using the anti-reflective coating of the window wafer as an etch stop. After formation of the cavities, the bonded interposer/window wafer pair is bonded peripherally of die areas to the MEMS device wafer, with die area micromechanical elements sealed within respectively corresponding ones of the cavities.

A method for fabricating an electronic device is disclosed. In one example, the method comprises providing a semiconductor wafer, forming a plurality of cavities into the semiconductor wafer, filling a stabilization material into the cavities, fabricating a temporary panel by applying a cap sheet onto the semiconductor wafer, the cap sheet covering the cavities, singulating the temporary panel into a plurality of semiconductor devices, fabricating an embedded wafer by embedding the semiconductor devices in an encapsulant, removing the cap sheet of each one of the semiconductor devices, and singulating the embedded wafer into a plurality of electronic devices.