Virtually all of the many active matter systems studied so far are made of units (biofilaments, cells, colloidal particles, robots, animals, etc.) that move even when they are alone or isolated. Their collective properties continue to fascinate and we now understand better how they are unique to the bulk transduction of energy into work.
A recent work just published in PNAS demonstrates that systems in which isolated but potentially active particles do not move can exhibit specific and remarkable collective properties. Combining experiments, theory, and numerical simulations, this paper shows that such subcritical active matter can be realized with Quincke rollers.
Since the early work of Quincke at the end of the 19th century, it is well known that dielectric colloidal particles immersed in a conducting fluid subjected to a vertical DC electric field undergo an instability leading to their rotation in the fluid when the field strength E is large enough. When the particles are denser than the fluid, they rest on the bottom surface, and start rolling in an arbitrary horizontal direction beyond the instability onset Ec.
The collective dynamics of Quincke rollers have been studied in the supercritical regime E>Ec,. The recent PNAS publication shows that spectacular collective phenomena emerge also when working below Ec, essentially because particles near each other can start rolling even for E< Ec. The phenomena reported include fast activity waves reminiscent of excitable systems, and stable arbitrarily large self-standing vortices made of thousands of particles moving at the same speed.
These remarkable collective dynamics cannot be accounted for by models usually invoked to be valid for such systems. A new type of mathematical model, motivated by experimental results, is introduced and shown to account for all observed phenomena.
Reference:
“Activity waves and freestanding vortices in populations of subcritical Quincke rollers” ,
Zeng Tao Liu, Yan Shi, Yongfeng Zhao, Hugues Chaté, Xia-qing Shi, and Tian Hui Zhang, PNAS 118 (40) e2104724118 (2021)
Contact CEA-IRAMIS : Hugues Chaté (SPEC/SPHYNX)
Collaboration:
Z.T. Liu, Y. Shi, Y. Zhao, H. Chaté, X.-q. Shi, and T.H. Zhang, Center for Soft Condensed Matter Physics and Interdisciplinary Research, Soochow University, Suzhou 215006, China.