The first law of thermodynamics in hydrodynamic steady and unsteady flows

Abstract

We studied planar compressible flows of ideal gas as models of a non-equilibrium thermodynamic system. We demonstrate that internal energy U(S*,V,N) of such systems in stationary and non-stationary states is the function of only three parameters of state, i.e. non-equilibrium entropy S*, volume V and number of particles N in the system. Upon transition between different states, the system obeys the first thermodynamic law, i.e. dU=T*dS*-p*dV+μ*dN, where U=3/2 NRT* and p*V=NRT*. Placing a cylinder inside the channel, we find that U depends on the location of the cylinder yc only via the parameters of state, i.e. U(S*(yc),V,N(yc)) at V=const. Moreover, when the flow around the cylinder becomes unstable, and velocity, pressure, and density start to oscillate as a function of time, t, U depends on t only via the parameters of state, i.e. U(S*(t),V,N(t)) for V=const. These examples show that such a form of internal energy is robust and does not depend on the particular boundary conditions even in the unsteady flow.