Atomistic mechanisms of viscosity in 2D liquid-like fluids

Abstract: Shear viscosity plays a fundamental role in fluid dynamics from heavy-ion collisions to biological processes. Still, its microscopic mechanisms at the individual particle kinetic level remain a subject of ongoing research, specially in dense systems. In this work, we systematically investigate the shear viscosity ($\eta$) of two-dimensional (2D) simple fluids using computer simulations of Lennard-Jones, Yukawa, and one-component plasma systems. By combining Frenkel's liquid description, consisting of solid-like quasi-harmonic vibrations interrupted by thermally activated hops, with the concept of lifetime of local atomic connectivity $\tau_{LC}$, we find a surprisingly simple formula for the kinematic viscosity that is solely determined by $\tau_{LC}$ and the average kinetic particle speed $\bar{v}p$. The derived analytical expression provides a direct link between macroscopic and microscopic dynamics, which shows excellent agreement with the simulation data in the dense liquid-like regime in all the 2D fluids considered. Moreover, it is discovered that, $\tau{LC}$ in 2D fluids is universally determined by the effective potential difference between the first peak and valley of the pair correlation function, implying a direct connection between macroscopic shear transport and microscopic structure. Finally, we demonstrate that the characteristic length scale $l_p= \bar{v}p \tau{LC}$, which governs the macroscopic shear viscosity, aligns with the elastic length-scale that defines the propagation limit of collective shear waves in liquids. These findings establish that shear viscosity in 2D fluids arises from the diffusive transport of average particle momentum across the elastic length scale. Moreover, they highlight that shear dynamics are fundamentally governed by localized configurational excitations within the atomic connectivity network.