A MEM array may comprise a first stage comprising a first stage reflective surface, and a second stage comprising a second stage reflective surface. The MEM array may comprise a base wafer positioned below the first stage and the second stage; and a first frame pivotally coupled to the first stage. The first frame may be pivotally coupled to a second frame, which may comprise a second frame high aspect ratio (AR) member that may be operable to reduce mechanical motion of the second stage.

A device includes: a first sidewall including a first opening extending through the first sidewall; a first sensor attached to an interior surface of the first sidewall, wherein the first sensor is aligned to at least partially cover the first opening; a second sidewall opposite the first sidewall; a third sidewall attaching the first sidewall to the second sidewall; and a first contact pad disposed on an exterior surface of the third sidewall, wherein the first contact pad is configured to provide at least one of a power connection or a signal connection for the first sensor.

In one embodiment of the present invention, an electronic device includes a first emitter/collector region and a second emitter/collector region disposed in a substrate. The first emitter/collector region has a first edge/tip, and the second emitter/collector region has a second edge/tip. A gap separates the first edge/tip from the second edge/tip. The first emitter/collector region, the second emitter/collector region, and the gap form a field emission device.

Disclosed herein are MEMS devices and systems and methods of manufacturing or operating the MEMS devices and systems. In some embodiments, the MEMS devices and systems are used in imaging applications.

An anti-fouling surface having micron scale pillars embedded with Fe.sub.3O.sub.4 nanoparticles is designed. The pillars may be repeatedly induced to move according to a predetermined frequency, such as one that mimic that of the beating movement of natural cilia, through the application of a magnetic field. When square-shaped pillars with a height of 10 m, width of 2 m, and inter-pattern distance of 5 m actuated for three minutes, more than 99.9 percent of biofilm cells were detached and via gentle rinsing from the surface having the pillars. The anti-fouling surface enables effective prevention of biofilm formation and removal of established biofilms, and can be applied to a broad spectrum of polymers.

An apparatus includes a cavity within a substrate. A MEMS structure is within the cavity, wherein the cavity includes the MEMS structure. A trench is connected to the cavity, wherein the trench is not directly opposite the MEMS structure. An oxide layer lines the trench and the cavity. A seal layer seals the trench and traps a predetermined pressure within the cavity and the trench.

A method of manufacturing a semiconductor device is provided. A first substrate is bonded with a second substrate. The second substrate is recessed to form a first sidewall and a first cavity laterally defined by the first sidewall. The second substrate is recessed to form a second sidewall and a second cavity laterally defined by the second sidewall. The second substrate is bonded with a third substrate at a first barometric pressure thereby forming the first cavity and the second cavity. The first sidewall is recessed to form a channel from the first cavity to an outer surface of the first sidewall. The third substrate is recessed and the first cavity is exposed to a second barometric pressure different from the first barometric pressure.

A method of manufacturing a semiconductor device is provided. A first substrate is bonded with a second substrate. The second substrate is recessed to form a first sidewall and a first cavity laterally defined by the first sidewall. The second substrate is recessed to form a second sidewall and a second cavity laterally defined by the second sidewall. The second substrate is bonded with a third substrate at a first barometric pressure thereby forming the first cavity and the second cavity. The first sidewall is recessed to form a channel from the first cavity to an outer surface of the first sidewall. The third substrate is recessed and the first cavity is exposed to a second barometric pressure different from the first barometric pressure.

A silicon carbide based MOS integrated circuit is monolithically integrated with a suspended piezoelectric aluminum nitride member to form a high-temperature-capable hybrid MEMS-over-MOS structure. In the integrated structure, a post-MOS passivation layer of silicon carbide is deposited over the MOS passivation and overlain by a structural layer of the MEMS device. Electrical contact to refractory metal conductors of the MOS integrated circuit is provided by tungsten vias that are formed so as to pass vertically through the structural layer and the post-MOS passivation layer.

An environmental sensor and manufacturing method thereof. The environmental sensor comprises: a substrate comprising at least one recess disposed at an upper portion of the substrate; and a sensitive film layer disposed above the substrate, comprising a fixed portion fixed on an end surface of the substrate and a bent portion configured to extend inside the recess. The bent portion and a side wall of the recess form a capacitor configured to detect a signal. The bent portion, fixed portion, and the recess form a closed cavity. A conventional capacitive structure configured on a substrate surface is changed to a capacitive structure of the environmental sensor vertically extending into the inside of the substrate, increasing a depth of the recess, and in turn, increasing a sensing area between two polar plates of the capacitor, significantly shrinking a coverage area of the capacitor on the substrate, and satisfying a requirement of a modern compact electronic component.