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Engineered artificial cilia create programmable liquid flows for microfluidic applications. This new metasurface technology enables precise control of microscale fluid dynamics using electronic actuation and wireless operation.

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Area of Science:

  • Microfluidics
  • Biomimetics
  • Materials Science

Background:

  • Biological cilia efficiently manipulate fluids at the microscale.
  • Engineered ciliary platforms face challenges in achieving controllable fluid manipulation.
  • Existing actuation methods (optical, magnetic, electrical) have limitations for practical applications.

Purpose of the Study:

  • To develop an active metasurface of electronically actuated artificial cilia.
  • To demonstrate the ability to create arbitrary and switchable surface flow patterns.
  • To enable wireless operation and improved pumping efficiency through metachronal waves.

Main Methods:

  • Fabrication of voltage-actuated artificial cilia generating non-reciprocal motion.
  • Design of cilia unit cells capable of creating elemental flow geometries.
  • Integration with a light-powered complementary metal-oxide-semiconductor (CMOS) clock circuit for wireless control.
  • Experimental demonstration and theoretical computation of flow patterns and pumping efficiency.

Main Results:

  • Achieved surface flows at tens of microns per second with low actuation voltages (1V).
  • Demonstrated local control over elemental flow geometries using individual cilia unit cells.
  • Successfully created an active metasurface capable of generating and switching between arbitrary flow patterns.
  • Validated wireless operation and improved pumping efficiency using metachronal waves via a CMOS circuit.

Conclusions:

  • Active metasurfaces of electronically actuated artificial cilia offer a novel approach for microfluidic manipulation.
  • The developed platform allows for precise, programmable control of fluid dynamics at the microscale.
  • This technology holds significant potential for applications in microfluidic pumping, microrobotics, and lab-on-a-chip devices.