Litcius/Paper detail

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, Saravanan Arumugam, Garima Arora, Swarnima Singh, Abhijit Sen, А. В. Тимофеев

2022Scientific Reports19 citationsDOIOpen Access PDF

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.

Topics & Concepts

PlasmaChemical physicsDusty plasmaThermodynamic equilibriumPhysicsParticle (ecology)Complex systemEnergy transformationAtomic physicsMechanicsMaterials scienceThermodynamicsComputer scienceOceanographyQuantum mechanicsArtificial intelligenceGeologyDust and Plasma Wave PhenomenaQuantum Electrodynamics and Casimir Effect