A micro-electro-mechanical device, comprising a monolithic body of semiconductor material accommodating a first buried cavity; a sensitive region facing the first buried cavity; a second cavity facing the first buried cavity; a decoupling trench extending from the monolithic body and separating the sensitive region from a peripheral portion of the monolithic body; a cap die, forming an ASIC, bonded to and facing the first face of the monolithic body; and a first gap between the cap die and the monolithic body. The device also comprises at least one spacer element between the monolithic body and the cap die; at least one stopper element between the monolithic body and the cap die; and a second gap between the stopper element and one between the monolithic body and the cap die. The second gap is smaller than the first gap.

Methods for improving wafer bonding performance are disclosed herein. In some embodiments, a method for bonding a pair of semiconductor substrates is disclosed. The method includes: processing at least one of the pair of semiconductor substrates, and bonding the pair of semiconductor substrates together. Each of the pair of semiconductor substrates is processed by: performing at least one chemical vapor deposition (CVD), and performing at least one chemical mechanical polishing (CMP). One of the at least one CVD is performed after all CMP performed before bonding.

A method of processing a double sided wafer of a microelectromechanical device includes spinning a resist onto a first side of a first wafer. The method further includes forming pathways within the resist to expose portions of the first side of the first wafer. The method also includes etching one or more depressions in the first side of the first wafer through the pathways, where each of the depressions have a planar surface and edges. Furthermore, the method includes depositing one or more adhesion metals over the resist such that the one or more adhesion metals are deposited within the depressions, and then removing the resist from the first wafer. The method finally includes depositing indium onto the adhesion metals deposited within the depressions and bonding a second wafer to the first wafer by compressing the indium between the second wafer and the first wafer.

Provided are integrated analysis devices having features of macroscale and nanoscale dimensions, and devices that have reduced background signals and that reduce quenching of fluorophores disposed within the devices. Related methods of manufacturing these devices and of using these devices are also provided.

A MEMS device includes a substrate which has a first main surface and a second main surface facing the first main surface, and in which a silicon substrate, a silicon carbide layer having conductivity, and a silicon layer are sequentially stacked from a second main surface side toward a first main surface side, a cavity recessed over the silicon layer, the silicon carbide layer, and the silicon substrate from the first main surface of the substrate to the second main surface side of the substrate, a MEMS electrode which is arranged in the cavity, is composed of the silicon layer and the silicon carbide layer, and is spaced apart from a bottom surface of the cavity to the first main surface side, and an isolation joint which divides the MEMS electrode in a plan view and mechanically connects and electrically isolates both sides of the divided MEMS electrode.

A process for fabricating a symmetrical MEMS accelerometer. A pair of half parts is fabricated by, for each half part: (i) forming a plurality of resilient beams, first connecting parts, second connecting parts, and a plurality of comb structures, by etching a plurality of holes on a bottom surface of a first silicon wafer; (ii) etching a plurality of hollowed parts on a top surface of a second silicon wafer; (iii) forming a silicon dioxide layer on the top and bottom surface of the second silicon wafer; (iv) bonding the bottom surface of the first silicon wafer with the top surface of the second silicon wafer; (v) depositing a layer of silicon nitride on the bottom surface of the second silicon wafer, and removing parts of the silicon nitride layer and silicon dioxide layer on the bottom surface of the second silicon wafer; (vii) deep etching the exposed parts of the bottom surface of the second silicon wafer to the silicon dioxide layer located on the top surface of the second silicon wafer, and reducing the thickness of the first silicon wafer; and (viii) removing the silicon nitride layer, and etching the silicon dioxide to form the mass. The two half parts are then bonded along their bottom surface. The device is deep etched to form a movable accelerometer. A bottom cap is fabricated by hollowing out the corresponding area, and depositing metal as electrodes. The accelerometer is bonded with the bottom cap. Metal is deposited on the first silicon wafer to form electrodes.

The present disclosure provides a semiconductor device. The semiconductor device includes a substrate, a metallization layer over the substrate, and a sensing structure over the metallization layer. The sensing structure includes an outgassing layer over the metallization layer, a patterned outgassing barrier in proximity to a top surface of the outgassing layer, the patterned outgassing barrier exposing a portion of the outgassing layer, and an electrode over the patterned outgassing barrier. The method for manufacturing the semiconductor device is also provided.

Nanopore flow cells and methods of manufacturing thereof are provided herein. In one embodiment a method of forming a flow cell includes forming a multi-layer stack on a first substrate, e.g., a monocrystalline silicon substrate, before transferring the multi-layer stack to a second substrate, e.g., a glass substrate. Here, the multi-layer stack features a membrane layer, having a first opening formed therethrough, where the membrane layer is disposed on the first substrate, and a material layer is disposed on the membrane layer. The method further includes patterning the second substrate to form a second opening therein and bonding the patterned surface of the second substrate to a surface of the multi-layer stack. The method further includes thinning the first substrate and thinning the second substrate. Here, the second substrate is thinned to where the second opening is disposed therethrough. The method further includes removing the thinned first substrate and at least portions of the material layer to expose opposite surfaces of the membrane layer.

A microelectromechanical device having a first substrate of semiconductor material and a second substrate of semiconductor material having a bonding recess delimited by projecting portions, monolithic therewith. The bonding recess forms a closed cavity with the first substrate. A bonding structure is arranged within the closed cavity and is bonded to the first and second substrates. A microelectromechanical structure is formed in a substrate chosen between the first and second substrates. The device is manufactured by forming the bonding recess in a first wafer; depositing a bonding mass in the bonding recess, the bonding mass having a greater depth than the bonding recess; and bonding the two wafers.

Described is a micro-haptic actuator device that can be fabricated with roll-to-roll MEMS processing techniques. The device includes a first body having a first surface and a second, opposing surface, the body has a chamber defined by at least one interior wall, a piston member disposed in the chamber, physically spaced from the at least one interior wall of the chamber, the piston member having a first surface and a second opposing surface. A membrane layer is disposed over and attached to the first surface of the body, with a portion of the membrane attached to the first surface of the piston member. The device also includes a first electrode supported on a second surface the membrane, and a second body that supports a second electrode, with the second body attached to the second surface of the first body.