A Geometric Heat-Flow Theory of Lagrangian Coherent Structures

Karrasch, Daniel; Keller, Johannes

doi:10.1007/s00332-020-09626-9

Cited by 25 publications

(38 citation statements)

References 92 publications

(176 reference statements)

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“…We show that leading order asymptotics that hold for functions [Krol, 1991] extend to the dominant nontrivial singular value. This answers questions raised in [Karrasch & Keller, 2020]. The generator of the time-averaged diffusion/heat semigroup is a Laplace operator associated to a weighted manifold structure on the material manifold.…”

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confidence: 73%

A Lagrangian perspective on nonautonomous advection-diffusion processes in the low-diffusivity limit

Karrasch,

Schilling

2021

Preprint

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We study mass preserving transport of passive tracers in the lowdiffusivity limit using Lagrangian coordinates. Over finite-time intervals, the solution-operator of the nonautonomous diffusion equation is approximated by that of a time-averaged diffusion equation. We show that leading order asymptotics that hold for functions [Krol, 1991] extend to the dominant nontrivial singular value. This answers questions raised in [Karrasch & Keller, 2020]. The generator of the time-averaged diffusion/heat semigroup is a Laplace operator associated to a weighted manifold structure on the material manifold. We show how geometrical properties of this weighted manifold directly lead to physical transport quantities of the nonautonomous equation in the low-diffusivity limit.

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confidence: 73%

A Lagrangian perspective on nonautonomous advection-diffusion processes in the low-diffusivity limit

Karrasch,

Schilling

2021

Preprint

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“…In other words, the dynamic Laplace operator is (twice) the generator of the dominant spatial process y t in (21) as a → ∞. The expression for Σ appears as a harmonic mean of the metrics g t in [KK20]; here it arises naturally in the limit of speeding up time in the temporal diffusion.…”

Section: The Dynamic Laplace Operator As the Averaging-limitmentioning

confidence: 99%

Detecting the birth and death of finite-time coherent sets

Froyland¹,

Koltai²

2021

Preprint

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Finite-time coherent sets (FTCSs) are distinguished regions of phase space that resist mixing with the surrounding space for some finite period of time; physical manifestations include eddies and vortices in the ocean and atmosphere, respectively. The boundaries of finite-time coherent sets are examples of Lagrangian coherent structures (LCSs). The selection of the time duration over which FTCS and LCS computations are made in practice is crucial to their success. If this time is longer than the lifetime of coherence of individual objects then existing methods will fail to detect the shorter-lived coherence. It is of clear practical interest to determine the full lifetime of coherent objects, but in complicated practical situations, for example a field of ocean eddies with varying lifetimes, this is impossible with existing approaches. Moreover, determining the timing of emergence and destruction of coherent sets is of significant scientific interest. In this work we introduce new constructions to address these issues. The key components are an inflated dynamic Laplace operator and the concept of semi-material FTCSs. We make strong mathematical connections between the inflated dynamic Laplacian and the standard dynamic Laplacian [Fro15], showing that the latter arises as a limit of the former. The spectrum and eigenfunctions of the inflated dynamic Laplacian directly provide information on the number, lifetimes, and evolution of coherent sets.

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“…We refer to the techniques falling into this second category as operator based methods, which have been introduced by Froyland et al (2007Froyland et al ( , 2008. Different types of coherent structures, called "coherent sets", can be extracted from spectral decompositions of the operator L (Froyland (2013); Froyland and Kwok (2016); Karrasch and Keller (2020)), which correspond to sets of simple geometry mixing slowly with their complement (Froyland et al (2010); Froyland (2015)). This approach yields by nature coherent structures that are subdomains and not codimension-one sets (Froyland and Kwok (2016)); in the autonomous case, codimension-one "coherent" surfaces can also be extracted from the invariant sets of (1) by resorting to ergodic theory (Mezić and Banaszuk (2004); Levnajić and Mezić (2010); Budisić and Mezić (2012)).…”

Section: Introductionmentioning

confidence: 99%

Rigid Sets and Coherent Sets in Realistic Ocean Flows

Feppon

Lermusiaux

2022

Preprint

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Abstract. This paper focuses on the extractions of Lagrangian Coherent Sets from realistic velocity fields obtained from ocean data and simulations, each of which can be highly resolved and non volume-preserving. We introduce two novel methods for computing two formulations of such sets. First, we propose a new “diffeomorphism-based” criterion to extract “rigid sets”, defined as sets over which the flow map acts approximately as a rigid transformation. Second, we develop a matrix-free methodology that provides a simple and efficient framework to compute “coherent sets” with operator methods. Both new methods and their resulting rigid sets and coherent sets are illustrated and compared using three numerically simulated flow examples, including a high-resolution realistic, submesoscale to large-scale dynamic ocean current field in the Palau Island region of the western Pacific Ocean.

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A Geometric Heat-Flow Theory of Lagrangian Coherent Structures

Cited by 25 publications

References 92 publications

A Lagrangian perspective on nonautonomous advection-diffusion processes in the low-diffusivity limit

A Lagrangian perspective on nonautonomous advection-diffusion processes in the low-diffusivity limit

Detecting the birth and death of finite-time coherent sets

Rigid Sets and Coherent Sets in Realistic Ocean Flows

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