Abstract
We consider Lagrangian coherent structures (LCSs) as the boundaries of material subsets whose advective evolution is metastable under weak diffusion. For their detection, we first transform the Eulerian advection–diffusion equation to Lagrangian coordinates, in which it takes the form of a time-dependent diffusion or heat equation. By this coordinate transformation, the reversible effects of advection are separated from the irreversible joint effects of advection and diffusion. In this framework, LCSs express themselves as (boundaries of) metastable sets under the Lagrangian diffusion process. In the case of spatially homogeneous isotropic diffusion, averaging the time-dependent family of Lagrangian diffusion operators yields Froyland’s dynamic Laplacian. In the associated geometric heat equation, the distribution of heat is governed by the dynamically induced intrinsic geometry on the material manifold, to which we refer as the geometry of mixing. We study and visualize this geometry in detail, and discuss connections between geometric features and LCSs viewed as diffusion barriers in two numerical examples. Our approach facilitates the discovery of connections between some prominent methods for coherent structure detection: the dynamic isoperimetry methodology, the variational geometric approaches to elliptic LCSs, a class of graph Laplacian-based methods and the effective diffusivity framework used in physical oceanography.
Highlights
Understanding the distribution of physical quantities by advection–diffusion is of fundamental importance in many scientific disciplines, including turbulent fluid dynamics and molecular dynamics
For a visual proof of coherence, we provide an advection movie showing the evolution of the Lagrangian coherent structures as Supplementary Material 1
In support of the decomposition of the fluid domain M into regular/coherent and mixing regions, we look at the action of the geometric heat flow induced by gon two different initial scalar distributions in the context of Example 1, the transient double gyre
Summary
Understanding the distribution of physical quantities by advection–diffusion is of fundamental importance in many scientific disciplines, including turbulent (geophysical) fluid dynamics and molecular dynamics. Of particular interest are coherent structures, for which there exist many phenomenological descriptions, visual diagnostics and mathematical approaches; see Hadjighasem et al (2017) for a recent review. Coherent structures are often thought of as rotating islands of particles with regular motion, which move in an otherwise turbulent background (McWilliams 1984; Fazle Hussain 1986; Provenzale 1999; Haller and Beron-Vera 2013). There exist geometric and topological approaches to coherence; see Ma and Bollt (2014, 2015b) and Allshouse and Thiffeault (2012), respectively Comparison studies of these methods have been restricted to simulation case studies (Allshouse and Peacock 2015; Ma and Bollt 2015a; Hadjighasem et al 2017) so far. We develop a unifying framework for the study of coherence from the Lagrangian viewpoint on advection–diffusion and provide new mathematical connections between
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