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Wireless actuation with functional acoustic surfaces

2016

Article

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Miniaturization calls for micro-actuators that can be powered wirelessly and addressed individually. Here, we develop functional surfaces consisting of arrays of acoustically resonant microcavities, and we demonstrate their application as two-dimensional wireless actuators. When remotely powered by an acoustic field, the surfaces provide highly directional propulsive forces in fluids through acoustic streaming. A maximal force of similar to 0.45mN is measured on a 4 x 4 mm(2) functional surface. The response of the surfaces with bubbles of different sizes is characterized experimentally. This shows a marked peak around the micro-bubbles' resonance frequency, as estimated by both an analytical model and numerical simulations. The strong frequency dependence can be exploited to address different surfaces with different acoustic frequencies, thus achieving wireless actuation with multiple degrees of freedom. The use of the functional surfaces as wireless ready-to-attach actuators is demonstrated by implementing a wireless and bidirectional miniaturized rotary motor, which is 2.6 x 2.6 x 5 mm(3) in size and generates a stall torque of similar to 0.5 mN.mm. The adoption of micro-structured surfaces as wireless actuators opens new possibilities in the development of miniaturized devices and tools for fluidic environments that are accessible by low intensity ultrasound fields.

Author(s): Qiu, T. and Palagi, S. and Mark, A. G. and Melde, K. and Adams, F. and Fischer, P.
Journal: Appl. Phys. Lett.
Volume: 109
Number (issue): 19
Pages: 191602
Year: 2016
Month: November
Day: 5

Department(s): Micro, Nano, and Molecular Systems
Research Project(s): New wireless ultrasonic actuator and its application in miniaturized endoscopy
Bibtex Type: Article (article)

DOI: 10.1063/1.4967194
Note: APL Editor's pick. APL News.
State: Published
URL: http://aip.scitation.org/doi/abs/10.1063/1.4967194

BibTex

@article{2016qiu,
  title = {Wireless actuation with functional acoustic surfaces},
  author = {Qiu, T. and Palagi, S. and Mark, A. G. and Melde, K. and Adams, F. and Fischer, P.},
  journal = {Appl. Phys. Lett.},
  volume = {109},
  number = {19},
  pages = {191602},
  month = nov,
  year = {2016},
  note = {APL Editor's pick. APL News.},
  url = {http://aip.scitation.org/doi/abs/10.1063/1.4967194},
  month_numeric = {11}
}