Abstract: An improved electrically conductive membrane pump/transducer. The electrically conductive pump/transducer includes an array of electrically conductive membrane pumps that combine to generate a desired sound by moving a membrane (such as a membrane of PDMS), a piston, and/or by the use of pressurized airflow in the absence of such a membrane or piston. The electrically conductive membranes in the array can be, for example, graphene-polymer membranes. The electrically conductive pump can include mid-range, tweeter, and sub-woofer speakers.

Abstract: An improved electrically conductive membrane pump/transducer. The electrically conductive pump/transducer includes an array of electrically conductive membrane pumps that combine to generate a desired sound by moving a membrane (such as a membrane of PDMS), a piston, and/or by the use of pressurized airflow in the absence of such a membrane or piston. The electrically conductive membranes in the array can be, for example, graphene-polymer membranes. The electrically conductive pump can include mid-range, tweeter, and sub-woofer speakers.

Abstract: An improved electrically conductive membrane pump/transducer. The electrically conductive pump/transducer includes an array of electrically conductive membrane pumps that combine to move a larger membrane (such as a membrane of PDMS). The electrically conductive membranes in the array can be, for example, graphene-polymer membranes.

Abstract: An improved electrically conductive membrane pump/transducer. The electrically conductive pump/transducer includes an array of electrically conductive membrane pumps that combine to generate a desired sound by moving a membrane (such as a membrane of PDMS), a piston, and/or by the use of pressurized airflow in the absence of such a membrane or piston. The electrically conductive membranes in the array can be, for example, graphene-polymer membranes. The electrically conductive pump can include mid-range, tweeter, and sub-woofer speakers.

Abstract: An improved electrically conductive membrane pump/transducer. The electrically conductive pump/transducer includes an array of electrically conductive membrane pumps that combine to move a larger membrane (such as a membrane of PDMS). The electrically conductive membranes in the array can be, for example, graphene-polymer membranes.

Abstract: Nano-electromechanical systems (NEMS) devices that utilize thin electrically conductive membranes, which can be, for example, graphene membranes. The membrane-based NEMS devices can be used as sensors, electrical relays, adjustable angle mirror devices, variable impedance devices, and devices performing other functions.

Abstract: Nano-electromechanical systems (NEMS) devices that utilize thin electrically conductive membranes, which can be, for example, graphene membranes. The membrane-based NEMS devices can be used as sensors, electrical relays, adjustable angle mirror devices, variable impedance devices, and devices performing other functions.

Abstract: Nano-electromechanical systems (NEMS) devices that utilize thin electrically conductive membranes, which can be, for example, graphene membranes. The membrane-based NEMS devices can be used as sensors, electrical relays, adjustable angle mirror devices, variable impedance devices, and devices performing other functions.

Abstract: An improved an audio speaker having an electrostatic membrane pump. The electrostatic membrane pump can be an electrostatic graphene membrane pump. The method of making and using the audio speaker having the electrostatic membrane pump.

Abstract: The present invention relates to pump systems having graphene or other atomically thin electrically conductive materials supported by trough-shaped cavities.

Abstract: The present invention relates to graphene windows and methods for making same. One method comprises selecting a high purity metal foil, growing a layer of graphene on a first face of the metal foil, patterning the second face of the graphene-modified foil with a polymer, wherein the second face of the graphene-modified foil has an exposed region and etching the second face of the graphene-modified foil in the exposed region until exposing the first layer of graphene.

Abstract: Graphene materials having encapsulated gas cells and methods to make and use same. Alternative electrically conductive and atomically thin materials (such as graphene oxide) can be used alternatively or in addition to the graphene in the graphene encapsulated micro-bubble materials.

Abstract: The present invention relates to non-volatile memory chips having graphene drums. In some embodiments, the non-volatile memory chips have one or more layers that each includes a plurality of graphene-drum memory chip cells.

Abstract: An improved electrically conductive membrane pump/transducer, such as a graphene membrane transducer.

Abstract: The present invention relates to pump systems and engine systems having graphene drums. In embodiments of the invention, the graphene drum can be utilized in the main chambers and/or valves of the pumps and engines.

Abstract: The present invention relates to pump systems and engine systems having graphene drums. In embodiments of the invention, the graphene drum can be utilized in the main chambers and/or valves of the pumps and engines.

Abstract: The present invention relates to pump systems and engine systems having graphene drums. In embodiments of the invention, the graphene drum can be utilized in the main chambers and/or valves of the pumps and engines.

Abstract: A nanoelectromechanical tunneling current switch includes a cantilevered nanofilament including a secured end and an unsecured end and a conductor with a surface substantially perpendicular to a longitudinal axis of the nanofilament when the nanofilament is undeflected. The nanofilament is positioned with respect to the conductor to define a gap between the unsecured end of the nanofilament and the surface of the conductor substantially perpendicular to the longitudinal axis of the nanofilament. The nanofilament and the conductor are electrically connected by a circuit, and a tunneling current is configured to flow from the nanofilament to the surface of the conductor substantially perpendicular to the longitudinal axis of the nanofilament. In other embodiments of the nanoelectromechanical tunneling current switch, an electrically conductive membrane can be utilized in place of, or in addition to, the cantilevered nanofilament.

Abstract: A switching element having an electromechanical switch (such as an electrically conductive membrane switch, for example a graphene membrane switch) is disclosed herein. Such a switching element can be made and used in a switching power converter to reduce power loss and to maximize efficiency of the switching power converter.

Abstract: A nanoelectromechanical tunneling current switch includes a cantilevered nanofilament including a secured end and an unsecured end and a conductor with a surface substantially perpendicular to a longitudinal axis of the nanofilament when the nanofilament is undeflected. The nanofilament is positioned with respect to the conductor to define a gap between the unsecured end of the nanofilament and the surface of the conductor substantially perpendicular to the longitudinal axis of the nanofilament. The nanofilament and the conductor are electrically connected by a circuit, and a tunneling current is configured to flow from the nanofilament to the surface of the conductor substantially perpendicular to the longitudinal axis of the nanofilament. In other embodiments of the nanoelectromechanical tunneling current switch, an electrically conductive membrane can be utilized in place of, or in addition to, the cantilevered nanofilament.