Scientific Reports (Aug 2022)

Self-sustained non-equilibrium co-existence of fluid and solid states in a strongly coupled complex plasma system

  • M. G. Hariprasad,
  • P. Bandyopadhyay,
  • V. S. Nikolaev,
  • D. A. Kolotinskii,
  • S. Arumugam,
  • G. Arora,
  • S. Singh,
  • A. Sen,
  • A. V. Timofeev

DOI
https://doi.org/10.1038/s41598-022-17939-w
Journal volume & issue
Vol. 12, no. 1
pp. 1 – 12

Abstract

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Abstract A complex (dusty) plasma system is well known as a paradigmatic model for studying the kinetics of solid-liquid phase transitions in inactive condensed matter. At the same time, under certain conditions a complex plasma system can also display characteristics of an active medium with the micron-sized particles converting energy of the ambient environment into motility and thereby becoming active. We present a detailed analysis of the experimental complex plasmas system that shows evidence of a non-equilibrium stationary coexistence between a cold crystalline and a hot fluid state in the structure due to the conversion of plasma energy into the motion energy of microparticles in the central region of the system. The plasma mediated non-reciprocal interaction between the dust particles is the underlying mechanism for the enormous heating of the central subsystem, and it acts as a micro-scale energy source that keeps the central subsystem in the molten state. Accurate multiscale simulations of the system based on combined molecular dynamics and particle-in-cell approaches show that strong structural nonuniformity of the system under the action of electostatic trap makes development of instabilities a local process. We present both experimental tests conducted with a complex plasmas system in a DC glow discharge plasma and a detailed theoretical analysis.