An exemplary embodiment of the present disclosure provides a multiplexer/demultiplexer, comprising a plurality of unit cells arranged in a lattice, a first domain, a second domain, a third domain, and a controller. Each of the unit cells can comprise a topological-insulative material, a first piezoelectric patch, and a second piezoelectric patch. A first domain can comprise a first portion of the plurality of unit cells. A second domain can comprise a second portion of the plurality of unit cells. A third domain can comprise a third portion of the plurality of unit cells. The controller can be configured to: apply a negative capacitance to the first piezoelectric patches in the first domain; apply a negative capacitance to the second piezoelectric patches in the second domain; and alternately apply a negative capacitance to the first and second piezoelectric patches, respectively, in the third domain.

A piezoelectric device includes a support substrate, an intermediate layer on the support substrate in a first region, a piezoelectric layer on the intermediate layer, a functional element on the piezoelectric layer, and an insulating layer. The insulating layer is located on the support substrate in a second region adjacent to the first region. A surface roughness of the support substrate in the second region is greater than a surface roughness of the support substrate in the first region.

According to an example aspect of the present invention, there is provided a liquid handling device comprising: means for harvesting energy; energy storage arranged for storing the harvested energy in the liquid handling device; and an electronic component connected to the energy storage and configured to use the energy storage as a power source.

Some embodiments of the invention relate to an applicator for applying ultrasound energy to a tissue volume, comprising: an array comprising a plurality of ultrasound transducers, the transducers arranged side by side, the transducers configured to emit unfocused ultrasound energy suitable to thermally damage at least a portion of the tissue volume, each of the transducers comprising a coating thin enough so as not to substantially affect heat transfer via the coating to the tissue; and a cooling module configured to apply cooling via the transducers to prevent overheating of a surface of the tissue volume being contacted by the transducers.

A force sensing device is mounted on a tool to sense force, particularly quasi-static and static forces. The force sensing device includes at least one a sensor. A piezoelectric element in the sensor includes a driving portion and a sensing portion. A first voltage is input to the driving portion to generate a vibration in the piezoelectric element and a second voltage in response to the vibration is output from the sensing portion. The second voltage output from the sensing portion is changed as the vibration in the piezoelectric element is suppressed by an external force acting on the force sensing device so variation of the second voltage can be used to measure the external force.

Described herein are embodiments of fiber scanning systems and methods of scanning optical fibers. The disclosed systems and methods advantageously provide an improvement to the scanning range, the oscillation amplitude, and/or the maximum pointing angle for an optical fiber in a fiber scanning system by inducing a buckling of a portion of the optical fiber.

Various methods and systems are provided for a pulse circuit of a transmitter of an ultrasound system. In one example, the system may include a pulse circuit with transistors driving an ultrasound transducer of the ultrasound system, whereby the switching on and off of the transistors is mediated via one or more dynamic currents flowing from the gates of one or more of the transistors.

A piezoelectric transducer device includes a support, a piezoelectric element, a first connecting element and a second electrical connecting element, the piezoelectric element being carried by the support and each of the first and second electrical connecting elements being electrically connected, respectively, to a first area and a second area, distinct from the first area, of the piezoelectric element, the piezoelectric element including a lower face opposite the support and an upper face, opposite to the lower face, wherein the upper face is integrally exposed or is covered, partially or not, only with the second electrical connecting element.

A piezoelectric element, a piezoelectric vibrator and a manufacturing method and a driving method thereof, and an electronic device, and relates to field of piezoelectric technologies. According to the application, a piezoelectric structure is disposed on a first electrode and has an opening allowing the first electrode to penetrate through to be partially exposed, and a heat conducting structure is disposed in the opening. The opening penetrating through the piezoelectric structure is formed in the piezoelectric structure, such that the heating area is decreased when the piezoelectric structure vibrates, and heat generated by the piezoelectric structure is reduced, correspondingly; and the heat conducting structure is additionally disposed in the piezoelectric element to dissipate heat generated when the piezoelectric structure vibrates.

A projection exposure apparatus comprises a projection objective, and the projection objective comprises an optical device, wherein the optical device comprises an optical element having an optically effective surface and an electrostrictive actuator. The electrostrictive actuator is deformable by a control voltage being applied. The electrostrictive actuator is functionally connected to the optical element to influence the surface shape of the optically effective surface. A control device supplies the electrostrictive actuator with the control voltage. A measuring device is configured, at least at times while the electrostrictive actuator influences the optically effective surface of the optical element, to measure directly and/or to determine indirectly the temperature and/or a temperature change of the electrostrictive actuator and/or the surroundings thereof to take account of a temperature-dependent influence during driving of the electrostrictive actuator by the control device.