<p>Liquid metals have garnered widespread attention in the fields of electronics and materials science due to their unique combination of fluidity and electrical conductivity. Conventional liquid metal droplet generators typically rely on piezoelectric actuators to impose mechanical perturbations on the jet to control droplet formation. In this work, we present a new method for generating a uniform and controllable stream of liquid metal microdroplets by applying periodic electrostatic perturbations to the jet. Using a nozzle with an inner diameter of 25 µm, we achieved continuous generation of droplets approximately 51 µm in diameter at a frequency of 110 kHz. By adjusting the nozzle diameter, flow rate, and the frequency of the applied voltage, the size and spacing of the droplets can be effectively tuned. Moreover, a comparison between experimental observations and theoretical predictions under various conditions demonstrates that the Rayleigh-Plateau instability theory accurately describes the disturbance growth and droplet formation under electric field excitation. Our study provides both theoretical and experimental foundations for the controlled generation of gallium-based liquid metal droplets.</p>

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Electric field-driven uniform droplet generation of liquid metal

  • Zhi Deng,
  • Qiyou Liu,
  • Dingwei Zhang,
  • Hu Sun,
  • Liang Bai,
  • Bingqiang Ji,
  • Lijun Yang,
  • Qingfei Fu

摘要

Liquid metals have garnered widespread attention in the fields of electronics and materials science due to their unique combination of fluidity and electrical conductivity. Conventional liquid metal droplet generators typically rely on piezoelectric actuators to impose mechanical perturbations on the jet to control droplet formation. In this work, we present a new method for generating a uniform and controllable stream of liquid metal microdroplets by applying periodic electrostatic perturbations to the jet. Using a nozzle with an inner diameter of 25 µm, we achieved continuous generation of droplets approximately 51 µm in diameter at a frequency of 110 kHz. By adjusting the nozzle diameter, flow rate, and the frequency of the applied voltage, the size and spacing of the droplets can be effectively tuned. Moreover, a comparison between experimental observations and theoretical predictions under various conditions demonstrates that the Rayleigh-Plateau instability theory accurately describes the disturbance growth and droplet formation under electric field excitation. Our study provides both theoretical and experimental foundations for the controlled generation of gallium-based liquid metal droplets.