posted on 2021-04-21, 21:30authored byShuaizhong Zhang, Zhiwei Cui, Ye Wang, Jaap den Toonder
Biological cilia
often perform metachronal motion, that is, neighboring
cilia move out of phase creating a travelling wave, which enables
highly efficient fluid pumping and body locomotion. Current methods
for creating metachronal artificial cilia suffer from the complex
design and sophisticated actuation schemes. This paper demonstrates
a simple method to realize metachronal microscopic magnetic artificial
cilia (μMAC) through control over the paramagnetic particle
distribution within the μMAC based on their tendency to align
with an applied magnetic field. Actuated by a 2D rotating uniform
magnetic field, the metachronal μMAC enable strong microfluidic
pumping and soft robot locomotion. The metachronal μMAC induce
twice the pumping efficiency and 3 times the locomotion speed of synchronously
moving μMAC. The ciliated soft robots show an unprecedented
slope climbing ability (0 to 180°), and they display strong cargo-carrying
capacity (>10 times their own weight) in both dry and wet conditions.
These findings advance the design of on-chip integrated pumps and
versatile soft robots, among others.