English

The Simplest Viscous Flow

Chaotic Dynamics 2021-07-12 v4 Statistical Mechanics

Abstract

We illustrate an atomistic periodic two-dimensional stationary shear flow, ux= x˙ =ϵ˙yu_x = \langle \ \dot x \ \rangle = \dot \epsilon y, using the simplest possible example, the periodic shear of just two particles ! We use a short-ranged "realistic" pair potential, ϕ(r<2)=(2r)62(2r)3\phi(r<2) = (2-r)^6 - 2(2-r)^3. Many body simulations with it are capable of modelling the gas, liquid, and solid states of matter. A useful mechanics generating steady shear follows from a special ("Kewpie-Doll" \sim "qpqp-Doll") Hamiltonian based on the Hamiltonian coordinates {q}\{ q \} and momenta {p}\{ p \} : H(q,p)K(p)+Φ(q)+ϵ˙qp{\cal H}(q,p) \equiv K(p) + \Phi(q) + \dot \epsilon \sum qp. Choosing qpypxqp \rightarrow yp_x the resulting motion equations are consistent with steadily shearing periodic boundaries with a strain rate (dux/dy)=ϵ˙(du_x/dy) = \dot \epsilon. The occasional xx coordinate jumps associated with periodic boundary crossings in the yy direction provide a Hamiltonian that is a piecewise-continuous function of time. A time-periodic isothermal steady state results when the Hamiltonian motion equations are augmented with a continuously variable thermostat generalizing Shuichi Nos\'e's revolutionary ideas from 1984. The resulting distributions of coordinates and momenta are interesting multifractals, with surprising irreversible consequences from strictly time-reversible motion equations.

Keywords

Cite

@article{arxiv.2106.10788,
  title  = {The Simplest Viscous Flow},
  author = {William Graham Hoover and Carol Griswold Hoover},
  journal= {arXiv preprint arXiv:2106.10788},
  year   = {2021}
}

Comments

26 pages with 9 figures destined for CMST. Expanded Acknowledgement and Second-Order Runge-Kutta Addendum

R2 v1 2026-06-24T03:24:22.963Z