Abstract: The present subject matter relates to systems and methods for sealing one or more MEMS devices within an encapsulated cavity. A first material layer can be positioned on a substrate, the first material layer comprising a first cavity and a second cavity that each have one or more openings out of the first material layer. At least the first cavity can be exposed to a first atmosphere and sealed while it is exposed to the first atmosphere while not sealing the second cavity. The second cavity can then be exposed to a second atmosphere that is different than the first atmosphere, and the second cavity can be sealed while it is exposed to the second atmosphere.

Abstract: The present subject matter relates to MEMS tunable capacitors and methods for operating such capacitors. The tunable capacitor can feature a primary stationary actuator electrode on a substrate, a secondary stationary actuator electrode on the substrate, a stationary RF signal capacitor plate electrode on the substrate, a sprung cantilever disposed over the substrate, a beam anchor connecting a first end of the sprung cantilever to the substrate, and one or more elastic springs or other biasing members connecting a second end of the sprung cantilever to the substrate, the second end being located distally from the first end. The spring cantilever can be movable between an OFF state defined by the potential difference between the stationary and moveable actuator electrodes being zero, and an ON state defined by a non-zero potential difference between the stationary and moveable actuator electrodes.

Abstract: The present subject matter relates to the use of current splitting and routing techniques to distribute current uniformly among the various layers of a device to achieve a high Q-factor. Such current splitting can allow the use of relatively narrow interconnects and feeds while maintaining a high Q. Specifically, for example a micro-electromechanical systems (MEMS) device can comprise a metal layer comprising a first portion and a second portion that is electrically separated from the first portion. A first terminus can be independently connected to each of the first portion and the second portion of the metal layer, wherein the first portion defines a first path between the metal layer and the first terminus, and the second portion defines a second path between the metal layer and the first terminus.

Abstract: Methods and devices for fabricating tri-layer beams are provided. In particular, disclosed are methods and structures that can be used for fabricating multilayer structures through the deposition and patterning of at least an insulation layer, a first metal layer, a beam oxide layer, a second metal layer, and an insulation balance layer.

Abstract: Substrates with slotted metals and related methods are provided. According to one aspect, a slotted metal attached to a substrate can include a metal patterned with slots less than or about equal to 2 microns. The slots can result in line widths that are approximately the size of a single metallurgical grain in an unpatterned layer.

Abstract: The present subject matter relates to MEMS tunable capacitors and methods for operating such capacitors. The tunable capacitor can feature a primary stationary actuator electrode on a substrate, a secondary stationary actuator electrode on the substrate, a stationary RF signal capacitor plate electrode on the substrate, a sprung cantilever disposed over the substrate, a beam anchor connecting a first end of the sprung cantilever to the substrate, and one or more elastic springs or other biasing members connecting a second end of the sprung cantilever to the substrate, the second end being located distally from the first end. The spring cantilever can be movable between an OFF state defined by the potential difference between the stationary and moveable actuator electrodes being zero, and an ON state defined by a non-zero potential difference between the stationary and moveable actuator electrodes.

Abstract: Methods and devices for fabricating tri-layer beams are provided. In particular, disclosed are methods and structures that can be used for fabricating multilayer structures through the deposition and patterning of at least an insulation layer, a first metal layer, a beam oxide layer, a second metal layer, and an insulation balance layer.

Abstract: Substrates with slotted metals and related methods are provided. According to one aspect, a slotted metal attached to a substrate can include a metal patterned with slots less than or about equal to 2 microns. The slots can result in line widths that are approximately the size of a single metallurgical grain in an unpatterned layer.

Abstract: Micro-electro-mechanical system (MEMS) variable capacitor apparatuses, system and related methods are provided. According to one embodiment, a MEMS variable capacitor is provided. The variable capacitor can include first and second actuation electrodes being spaced apart, and at least one of the actuation electrodes being movable when a voltage is applied across the first and second actuation electrodes. Further, the variable capacitor can include a first capacitive electrode attached to the first actuation electrode. The variable capacitor can also include a second capacitive electrode attached to the second actuation electrode and spaced from the first capacitive electrode for movement of at least one of the capacitive electrodes with respect to the other capacitive electrode upon application of voltage across the first and second actuation electrodes to change the capacitance between the first and second capacitive electrodes.

Abstract: Methods for Implementation of a Switching Function in a Microscale Device and for Fabrication of a Microscale Switch. According to one embodiment, a method is provided for implementing a switching function in a microscale device. The method can include providing a stationary electrode and a stationary contact formed on a substrate. Further, a movable microcomponent suspended above the substrate can be provided. A voltage can be applied between the between a movable electrode of the microcomponent and the stationary electrode to electrostatically couple the movable electrode with the stationary electrode, whereby the movable component is deflected toward the substrate and a movable contact moves into contact with the stationary contact to permit an electrical signal to pass through the movable and stationary contacts. A current can be applied through the first electrothermal component to produce heating for generating force for moving the microcomponent.

Abstract: Micro-electro-mechanical system (MEMS) variable capacitor apparatuses, system and related methods are provided. According to one embodiment, a MEMS variable capacitor is provided. The variable capacitor can include first and second actuation electrodes being spaced apart, and at least one of the actuation electrodes being movable when a voltage is applied across the first and second actuation electrodes. Further, the variable capacitor can include a first capacitive electrode attached to the first actuation electrode. The variable capacitor can also include a second capacitive electrode attached to the second actuation electrode and spaced from the first capacitive electrode for movement of at least one of the capacitive electrodes with respect to the other capacitive electrode upon application of voltage across the first and second actuation electrodes to change the capacitance between the first and second capacitive electrodes.