Litcius/Paper detail

Origin of viscosity at individual particle level in Yukawa liquids

Dong Huang, Shaoyu Lü, Michael S. Murillo, Yan Feng

2022Physical Review Research24 citationsDOIOpen Access PDF

Abstract

The transition of the viscosity $\ensuremath{\eta}$ from a collisional gas through a minimum value to a correlated liquid is investigated using computer simulations with the Green-Kubo relation. It is discovered that, as the temperature varies, the transition of $\ensuremath{\eta}$ is well described by the unity ratio of the instantaneous transverse sound speed ${C}_{T}$ to the average particle speed ${\overline{v}}_{p}$. While ${C}_{T}/{\overline{v}}_{p}<1, \ensuremath{\eta}$ increases with the temperature, since in this regime the viscosity is dominated by the gaslike individual dynamics. However, when ${C}_{T}/{\overline{v}}_{p}>1$ where the cooperative dynamics dominates, the fundamental origin of viscosity of liquids is found to be just losing or gaining neighbors for individual particles, so that the viscosity of a typical liquid reasonably decreases with the temperature. Our results reveal that the viscosity transition point of ${C}_{T}/{\overline{v}}_{p}=1$ is just $\ensuremath{\approx}20$ times the corresponding melting point for both two-dimensional and three-dimensional Yukawa liquids with various screening parameters, which probably can be used as a new criterion to distinguish the strong and weak couplings in plasma physics.

Topics & Concepts

Yukawa potentialViscosityVolume viscosityPhysicsThermodynamicsMelting pointCondensed matter physicsMathematical physicsParticle physicsQuantum mechanicsDust and Plasma Wave PhenomenaMaterial Dynamics and PropertiesQuantum, superfluid, helium dynamics