According to various embodiments, a MEMS device includes a substrate, an electrically movable heating element having a first node coupled to a first terminal of a first voltage source and the second node coupled to a reference voltage source, a first anchor anchoring the first node and a second anchor anchoring the second node of the electrically movable heating element to the substrate, and a cavity between the first anchor and the second anchor and between the electrically movable heating element and the substrate.

On seed metal layer of first metal, pedestal and counter electrode are formed of second metal by plating, adjacent to free space region. The free space region is filled with first sacrificial layer. By using resist pattern, second sacrificial metal layer is formed, extending from the first sacrificial layer to a portion of the pedestal, and lower structure of third metal is formed on the second sacrificial layer, by contiguous plating, exposing a portion of the pedestal not formed with the second sacrificial layer, the third metal having composition and thermal expansion coefficient equivalent to the second metal. Upper structure of fourth metal having composition and thermal expansion coefficient equivalent to the second and third metals is formed on the pedestal and the lower structure by plating. The first and second sacrificial layers are removed, leaving an electric equipment with a movable portion.

According to one embodiment, a MEMS element includes a first member, and an element part. The element part includes a first fixed electrode fixed to the first member, and a first movable electrode facing the first fixed electrode, a first conductive member electrically connected with the first movable electrode, and a second conductive member electrically connected with the first movable electrode. The first movable electrode is supported by the first and second conductive members to be separated from the first fixed electrode in a first state before a first electrical signal is applied between the second conductive member and the first fixed electrode. The first conductive member is separated from the first movable electrode in a second state after the first electrical signal is applied. The first movable electrode is supported by the second conductive member to be separated from the first fixed electrode in the second state.

A hermetically sealed component may comprise a glass substrate, a device with at least one electrical port associated with the glass substrate, and a glass cap. The glass cap may have at least one side wall. The glass cap may have a shaped void extending therethrough, from top surface of the glass cap to bottom surface of glass pillar. An electrically conductive plug may be disposed within the void, the plug configured to hermetically seal the void. The electrically conductive plug may be electrically coupled to the electrical port. The glass cap may be disposed on the glass substrate, with the at least one side wall disposed therebetween, to form a cavity encompassing the device. The side wall may contact the glass substrate and the glass cap to provide a hermetic seal, such that a first environment within the cavity is isolated from a second environment external to the cavity.

A button device includes a fixed support structure; a movable structure, laterally surrounded by the support structure and configured to deform at least in part under the action of an external force; and a fluid-tight protection cap. The movable structure includes a piston element, deformable elements having piezoelectric transducers arranged thereon, and anchor elements that couple the piston element to the deformable elements. When an external force acts on the piston element, the anchor elements transfer this force to the deformable elements and to the piezoelectric transducers, so as to sense the extent of this force.

Button device comprising: a fixed support structure; a movable structure, laterally surrounded by said support structure and configured to deform at least in part under the action of an external force; and a fluid-tight protection cap. The movable structure includes a piston element, deformable elements having piezoelectric transducers arranged thereon, and anchor elements that couple the piston element to the deformable elements. When an external force acts on the piston element, the anchor elements transfer this force to the deformable elements and to the piezoelectric transducers, so as to sense the extent of this force.

A thermal metamaterial device comprises at least one MEMS thermal switch, comprising a substrate layer including a first material having a first thermal conductivity, and a thermal bus over a first portion of the substrate layer. The thermal bus includes a second material having a second thermal conductivity higher than the first thermal conductivity. An insulator layer is over a second portion of the substrate layer and includes a third material that is different from the first and second materials. A thermal pad is supported by a first portion of the insulator layer, the thermal pad including the second material and having an overhang portion located over a portion of the thermal bus. When a voltage is applied to the thermal pad, an electrostatic interaction occurs to cause a deflection of the overhang portion toward the thermal bus, thereby providing thermal conductivity between the thermal pad and the thermal bus.

A microelectromechanical systems (MEMS) device comprising: a substrate; a signal conductor supported on the substrate; ground conductors supported on the substrate on either side of the signal conductor; and a MEMS bridge at least one end of which is mechanically connected to the substrate by way of at least one anchor, the MEMS bridge comprising an electrically conductive switching portion, the electrically conductive switching portion comprising a switching signal conductor region and a switching ground conductor region, the switching signal conductor region being provided over the signal conductor and the switching ground conductor region being provided over a said ground conductor, the electrically conductive switching region being movable relative to the said signal and ground conductors respectively to thereby change the inductances between the switching signal conductor region and the signal conductor and between the switching ground conductor region and the respective ground conductor, wherein there is no continuous electrically conductive path extending from the switching conductor region to the at least one anchor. Capacative and ohmic switches, a varactor, a phase shifter, a tuneable power splitter/combiner, tuneable attenuator, SPDT switch and antenna apparatus comprising said devices.

According to one embodiment, a MEMS element includes a first member, and an element part. The element part includes a first fixed electrode fixed to the first member, and a first movable electrode facing the first fixed electrode, a first conductive member electrically connected with the first movable electrode, and a second conductive member electrically connected with the first movable electrode. The first movable electrode is supported by the first and second conductive members to be separated from the first fixed electrode in a first state before a first electrical signal is applied between the second conductive member and the first fixed electrode. The first conductive member is separated from the first movable electrode in a second state after the first electrical signal is applied. The first movable electrode is supported by the second conductive member to be separated from the first fixed electrode in the second state.

Compositions and methods related to multiaxially straining defect doped materials as well as their use in electrical circuits are generally described.