Lyapunov exponents and Lagrangian chaos suppression in compressible homogeneous isotropic turbulence (2310.09717v2)

Abstract: We study Lyapunov exponents of tracers in compressible homogeneous isotropic turbulence at different turbulent Mach number $M_t$ and Taylor-scale Reynolds number $Re_\lambda$. We demonstrate that statistics of finite-time Lyapunov exponents have the same form as in incompressible flow due to density-velocity coupling. Modulus of the smallest Lyapunov exponent $\lambda_3$ provides the principal Lyapunov exponent of the time-reversed flow, which usually is wrong in a compressible flow. This exponent, along with the principal Lyapunov exponent $\lambda_1$, determines all the exponents due to the vanishing of the sum of all Lyapunov exponents. Numerical results by high-order schemes for solving the Navier-Stokes equations and tracking particles verify these theoretical predictions. We found that: 1) The largest normalized Lyapunov exponent $\lambda_1 \tau_\eta$, where $\tau_\eta$ is the Kolmogorov time scale, is a decreasing function of $M_t$. Its dependence on $Re_\lambda$ is weak when the driving force is solenoidal, while it is an increasing function of $Re_\lambda$ when the solenoidal and compressible forces are comparable. Similar facts hold for $|\lambda_3|$, in contrast with well-studied short-correlated model; 2) The ratio of the first two Lyapunov exponents $\lambda_1/\lambda_2$ decreases with $Re_\lambda$, and is virtually independent of $M_t$ for $M_t \le 1$ in the case of solenoidal force but decreases as $M_t$ increases when solenoidal and compressible forces are comparable; 3) For purely solenoidal force, $\lambda_1 :\lambda_2 :\lambda_3 \approx 4:1:-5$ for $Re_\lambda > 80$, which is consistent with incompressible turbulence studies; 4) The ratio of dilation-to-vorticity is a more suitable parameter to characterize LEs than $M_t$.