Extraction of finite-time coherent sets in 3D Rayleigh-Benard Convection using the dynamic Laplacian

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Extraction of finite-time coherent sets in 3D Rayleigh-Benard Convection using the dynamic Laplacian. / Froyland, Gary; Klünker, Anna; Padberg-Gehle, Kathrin et al.
In: Bulletin of the American Physical Society, Vol. 65, No. 13, K08.00003, 2020.

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@article{c4babc2973fa4f8e92a78349b49c9183,
title = "Extraction of finite-time coherent sets in 3D Rayleigh-Benard Convection using the dynamic Laplacian",
abstract = "Extraction of nite-time coherent sets in 3D Rayleigh-BenardConvection using the dynamic LaplacianGARY FROYLAND, University ofNew South Wales, ANNA KLUENKER, KATHRIN PADBERG-GEHLE, CHRISTIANE SCHNEIDE, Leuphana University, JOERG SCHUMACHER, TechnicalUniversity Ilmenau | Turbulent convection ows in nature are often organized inregular large-scale patterns, which evolve slowly relative to to the typical convectivetimescale, and are arranged on spatial scales that are much larger than the layerheight. Prominent examples are cloud streets in the atmosphere and granulationpatterns in solar convection. This order in a fully developed turbulent ow is some-times called turbulent superstructure in convection. Large-scale structure formationin turbulent Rayleigh-Benard convection recently became accessible in direct numerical simulations, which resolve all relevant scales of turbulence in horizontally extended domains with a large aspect ratio. Using DNS output we apply the dynamicLaplacian approach [Froyland, 2015] to identify these turbulent superstructures as nite-time coherent sets in both quasi-2D and fully three-dimensional settings. Amodest number of trajectories are meshed and a nite-element based method isemployed to numerically estimate the dynamic Laplacian [Froyland Junge, 2018].The coherent sets are encoded in the leading eigenvectors of the dynamic Laplacian,and the individual coherent sets are \decoded{"} using the recently developed SparseEigenbasis Approximation (SEBA) algorithm [Froyland, Rock, Sakellariou, 2019]",
keywords = "Mathematics",
author = "Gary Froyland and Anna Kl{\"u}nker and Kathrin Padberg-Gehle and Christiane Schneide and J{\"o}rg Schumacher",
note = "Titel d. Ausgabe: 73rd Annual Meeting of the APS Division of Fluid Dynamics ; Virtual, CT (Chicago time); 73rd Annual Meeting of the APS Division of Fluid Dynamics - 2021 ; Conference date: 22-11-2020 Through 24-11-2020",
year = "2020",
language = "English",
volume = "65",
journal = "Bulletin of the American Physical Society",
issn = "0003-0503",
publisher = "American Physical Society",
number = "13",

}

RIS

TY - JOUR

T1 - Extraction of finite-time coherent sets in 3D Rayleigh-Benard Convection using the dynamic Laplacian

AU - Froyland, Gary

AU - Klünker, Anna

AU - Padberg-Gehle, Kathrin

AU - Schneide, Christiane

AU - Schumacher, Jörg

N1 - Conference code: 73

PY - 2020

Y1 - 2020

N2 - Extraction of nite-time coherent sets in 3D Rayleigh-BenardConvection using the dynamic LaplacianGARY FROYLAND, University ofNew South Wales, ANNA KLUENKER, KATHRIN PADBERG-GEHLE, CHRISTIANE SCHNEIDE, Leuphana University, JOERG SCHUMACHER, TechnicalUniversity Ilmenau | Turbulent convection ows in nature are often organized inregular large-scale patterns, which evolve slowly relative to to the typical convectivetimescale, and are arranged on spatial scales that are much larger than the layerheight. Prominent examples are cloud streets in the atmosphere and granulationpatterns in solar convection. This order in a fully developed turbulent ow is some-times called turbulent superstructure in convection. Large-scale structure formationin turbulent Rayleigh-Benard convection recently became accessible in direct numerical simulations, which resolve all relevant scales of turbulence in horizontally extended domains with a large aspect ratio. Using DNS output we apply the dynamicLaplacian approach [Froyland, 2015] to identify these turbulent superstructures as nite-time coherent sets in both quasi-2D and fully three-dimensional settings. Amodest number of trajectories are meshed and a nite-element based method isemployed to numerically estimate the dynamic Laplacian [Froyland Junge, 2018].The coherent sets are encoded in the leading eigenvectors of the dynamic Laplacian,and the individual coherent sets are \decoded" using the recently developed SparseEigenbasis Approximation (SEBA) algorithm [Froyland, Rock, Sakellariou, 2019]

AB - Extraction of nite-time coherent sets in 3D Rayleigh-BenardConvection using the dynamic LaplacianGARY FROYLAND, University ofNew South Wales, ANNA KLUENKER, KATHRIN PADBERG-GEHLE, CHRISTIANE SCHNEIDE, Leuphana University, JOERG SCHUMACHER, TechnicalUniversity Ilmenau | Turbulent convection ows in nature are often organized inregular large-scale patterns, which evolve slowly relative to to the typical convectivetimescale, and are arranged on spatial scales that are much larger than the layerheight. Prominent examples are cloud streets in the atmosphere and granulationpatterns in solar convection. This order in a fully developed turbulent ow is some-times called turbulent superstructure in convection. Large-scale structure formationin turbulent Rayleigh-Benard convection recently became accessible in direct numerical simulations, which resolve all relevant scales of turbulence in horizontally extended domains with a large aspect ratio. Using DNS output we apply the dynamicLaplacian approach [Froyland, 2015] to identify these turbulent superstructures as nite-time coherent sets in both quasi-2D and fully three-dimensional settings. Amodest number of trajectories are meshed and a nite-element based method isemployed to numerically estimate the dynamic Laplacian [Froyland Junge, 2018].The coherent sets are encoded in the leading eigenvectors of the dynamic Laplacian,and the individual coherent sets are \decoded" using the recently developed SparseEigenbasis Approximation (SEBA) algorithm [Froyland, Rock, Sakellariou, 2019]

KW - Mathematics

UR - http://flux.aps.org/meetings/YR20/DFD20/all_DFD20.pdf

M3 - Conference abstract in journal

VL - 65

JO - Bulletin of the American Physical Society

JF - Bulletin of the American Physical Society

SN - 0003-0503

IS - 13

M1 - K08.00003

T2 - 73rd Annual Meeting of the APS Division of Fluid Dynamics - 2021

Y2 - 22 November 2020 through 24 November 2020

ER -