Characterization of velocity-gradient dynamics in incompressible turbulence using local streamline geometry

Abstract

This study develops a comprehensive description of local streamline geometry and uses the resulting shape features to characterize velocity gradient (Aij) dynamics. The local streamline geometric shape parameters and scale-factor (size) are extracted from Aij by extending the linearized critical point analysis. In the present analysis, Aij is factorized into its magnitude (A AijAij) and normalized tensor bij Aij/A. The geometric shape is shown to be determined exclusively by four bij parameters -- second invariant, q; third invariant, r; intermediate strain-rate eigenvalue, a2; and, angle between vorticity and intermediate strain-rate eigenvector, ω2. Velocity gradient magnitude A plays a role only in determining the scale of the local streamline structure. Direct numerical simulation data of forced isotropic turbulence (Reλ 200 - 600) is used to establish streamline shape and scale distribution and, then to characterize velocity-gradient dynamics. Conditional mean trajectories (CMTs) in q-r space reveal important non-local features of pressure and viscous dynamics which are not evident from the Aij-invariants. Two distinct types of q-r CMTs demarcated by a separatrix are identified. The inner trajectories are dominated by inertia-pressure interactions and the viscous effects play a significant role only in the outer trajectories. Dynamical system characterization of inertial, pressure and viscous effects in the q-r phase space is developed. Additionally, it is shown that the residence time of q-r CMTs through different topologies correlate well with the corresponding population fractions. These findings not only lead to improved understanding of non-local dynamics, but also provide an important foundation for developing Lagrangian velocity-gradient models.