We report the application of a far-from-equilibrium statistical-mechanical theory to a nontrivial system with Newtonian interactions in continuous boundary-driven flow. By numerically time stepping the force-balance equations of a one-dimensional model fluid we measure occupancies and transition rates in simulation. The high-shear-rate simulation data reproduce the predicted invariant quantities, thus supporting the theory that a class of nonequilibrium steady states of matter, namely, sheared complex fluids, is amenable to statistical treatment from first principles. © 2010 The American Physical Society.

R. Aditi Simha

complex fluids

First-principles

Force balances

MECHANICAL THEORY

Newtonians

NON-EQUILIBRIUM STEADY STATE

One-dimensional model

SHEAR-RATE

SIMULATION DATA

STATISTICAL TREATMENT

TIME-STEPPING

Transition rates

Statistical mechanics

Computer simulation

Fulltext

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IIT Madras

Physical Review E - Statistical, Nonlinear, and Soft Matter Physics

We analyse the statistics of the shear stress in a one dimensional model fluid, that exhibits a rich phase behaviour akin to real complex fluids under shear. We show that the energy flux satisfies the Gallavotti-Cohen FT across all phases in the system. The theorem allows us to define an effective temperature which deviates considerably from the equilibrium temperature as the noise in the system increases. This deviation is negligible when the system size is small. The dependence of the effective temperature on the strain rate is phase-dependent. It doesn't vary much at the phase boundaries. The effective temperature can also be determined from the large deviation function of the energy flux. The local strain rate statistics obeys the large deviation principle and satisfies a fluctuation relation. It does not exhibit a distinct kink near zero strain rate because of inertia of the rotors in our system. © 2016 IOP Publishing Ltd and SISSA Medialab srl.

Journal of Statistical Mechanics: Theory and Experiment

Large deviation statistics of non-equilibrium fluctuations in a sheared model-fluid

Physical Review Letters

Test of the Additivity Principle for Current Fluctuations in a Model of Heat Conduction

Invariant Quantities in Shear Flow

Rheologica Acta

Perspectives on shear banding in complex fluids

Physical Review E

Properties of a nonequilibrium heat bath

Activated Dynamics and Effective Temperature in a Steady State Sheared Glass

Statistical mechanics far from equilibrium: Prediction and test for a sheared system

Journal	Physical Review E - Statistical, Nonlinear, and Soft Matter Physics
ISSN	15393755
Open Access	Yes