A silicon wafer includes a plurality of chip patterns arranged parallel to a first direction and a second direction intersecting the first direction, wherein the plurality of chip patterns include one or more patterns arranged in the first direction and the second direction in a straight line, the plurality of chip patterns include a first chip pattern and a second chip pattern adjacent to the first chip pattern, and the second chip pattern is arranged by rotating the first chip pattern at 90 degrees, the plurality of chip patterns are arranged so that an axis in which a cleavage plane of the silicon wafer and a surface arranged with the pattern on the silicon wafer intersect, and the first direction are different, and an angle between the axis and the first direction of the second chip pattern is 90 degrees.

A micromechanical structure, comprising a substrate having a through hole; a residual portion of a sacrificial oxide layer peripheral to the hole; and a polysilicon layer overlying the hole, patterned to have a planar portion; a supporting portion connecting the planar portion to polysilicon on the residual portion; polysilicon stiffeners formed extending beneath the planar portion overlying the hole; and polysilicon ribs surrounding the supporting portion, attached near a periphery of the planar portion. The polysilicon ribs extend to a depth beyond the stiffeners, and extend laterally beyond an edge of the planar portion. The polysilicon ribs are released from the substrate during manufacturing after the planar region, and reduce stress on the supporting portion.

The present invention relates to an easy, scalable method, relying on conventional and unconventional techniques, to incorporate tilt in the fabrication of synthetic polymer-based dry adhesives mimicking the gecko adhesive system. These dry, reversible adhesives demonstrate anisotropic adhesion properties, providing strong adhesion and friction forces when actuated in the gripping direction and an initial repulsive normal force and negligible friction when actuated in the releasing direction.

Described are transducer assemblies and imaging devices comprising: a microelectromechanical systems (MEMS) die including a plurality of piezoelectric elements; a complementary metal-oxide-semiconductor (CMOS) die electrically coupled to the MEMS die by a first plurality of bumps and including at least one circuit for controlling the plurality of piezoelectric elements; and a package secured to the CMOS die by an adhesive layer and electrically connected to the CMOS die.

A micro-relay switch array may comprise an array of micro-relays disposed on a substrate, and a cap disposed over the array of micro-relays, thereby encapsulating the array of micro-relays. The micro-relay switch array may further comprise an array of through-substrate vias (TSVs) associated with the array of micro-relays, arranged such that columns of TSVs alternate with columns of micro-relays, and a plurality of device electrical conductors, each of which electrically couples one of the TSVs of the array of TSVs directly to at least two of the micro-relays. The micro-relay switch array may further comprise a plurality of TSV electrical conductors, each of which electrically couples at least two TSVs together. Each micro-relay of the array of micro-relays may be a micro-electromechanical system (MEMS) switch. The substrate and cap may be glass, and the TSVs may be through-glass vias.

An example method of producing a microelectromechanical system (MEMS) package, the method comprising: applying first epoxy layers to a first substrate, at least one of the first epoxy layers coupled to a second substrate; applying a first post gel heat treatment to the first epoxy layers; after applying the first post gel heat treatment to the first epoxy layers, applying second epoxy layers to the second substrate and to the first epoxy layers; and applying a second post gel heat treatment to the first epoxy layers and the second epoxy layers.

Described are transducer assemblies and imaging devices comprising: a microelectromechanical systems (MEMS) die including a plurality of piezoelectric elements; a complementary metal-oxide-semiconductor (CMOS) die electrically coupled to the MEMS die by a first plurality of bumps and including at least one circuit for controlling the plurality of piezoelectric elements; and a package secured to the CMOS die by an adhesive layer and electrically connected to the CMOS die.

A microelectromechanical system (MEMS) device includes: a mechanical layer; a mirror; and a mirror via coupling the mechanical layer and the mirror. The mirror is laterally offset from the mechanical layer in a direction.

A mirror arrangement, for example for a lithography system, comprises: a plurality of mirror elements, for example in the form of MEMS mirror modules, for reflecting radiation; a plurality of carrier elements, each having a head region for accommodating one of the mirror elements; and a mount arrangement comprising insert openings, which are designed to accommodate a respective seat portion of the carrier elements. The plurality of carrier elements are accommodated with the seat portions in the insert openings in the mount arrangement. Each carrier element comprises a channel device for guiding a coolant, which comprises an inlet for the coolant and an outlet for the coolant.

Monolithic microelectromechanical systems (MEMS)-based spatial light modulators (SLM) are provided. Generally, the SLM includes a common electrode in or on a substrate, an electrostatically displaceable actuator including an actuator electrode suspended above an upper surface on the substrate, a first light reflective surface supported by and separated from the upper surface on the substrate by the actuator, and a driver monolithically integrated in the substrate below the SLM. The actuator includes a structural layer of tensile, amorphous silicon-germanium that also serves as an actuator electrode. The driver includes multiple layers of vias, metal interconnects, and complementary metal-oxide-semiconductor (CMOS) devices to electrically couple to the common electrode and actuator, and is operable to displace the actuator and first light reflective surface in response to voltages applied thereto.