The Boltzmann Entropy for Dense Fluids Not in Local Equilibrium
Abstract
We investigate, via computer simulations, the time evolution of the (Boltzmann) entropy of a dense fluid not in local equilibrium. The macrovariables M describing the system are the (empirical) particle density f=\f(x,v)\ and the total energy E. We find that S(ft,E) is monotone increasing in time even when its kinetic part is decreasing. We argue that for isolated Hamiltonian systems monotonicity of S(Mt) = S(MXt) should hold generally for ``typical'' (the overwhelming majority of) initial microstates (phase-points) X0 belonging to the initial macrostate M0, satisfying MX0 = M0. This is a direct consequence of Liouville's theorem when Mt evolves autonomously.
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