Front propagation in Rayleigh-Taylor systems with reaction

Andrea Scagliarini; L. Biferale; F. Mantovani; M. Pivanti; F. Pozzati; M. Sbragaglia; S.F. Schifano; F. Toschi; R. Tripicionne

doi:10.1088/1742-6596/318/9/092024

Front propagation in Rayleigh-Taylor systems with reaction

Andrea Scagliarini
, L. Biferale
, F. Mantovani
, M. Pivanti
, F. Pozzati
, M. Sbragaglia
, S.F. Schifano
, F. Toschi
, R. Tripicionne

Onderzoeksoutput: Hoofdstuk in Boek/Rapport/Congresprocedure › Conferentiebijdrage › Academic › peer review

4 Citaten (Scopus)

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A special feature of Rayleigh-Taylor systems with chemical reactions is the competition between turbulent mixing and the "burning processes", which leads to a highly non-trivial dynamics. We studied the problem performing high resolution numerical simulations of a 2d system, using a thermal lattice Boltzmann (LB) model. We spanned the various regimes emerging at changing the relative chemical/turbulent time scales, from slow to fast reaction; in the former case we found numerical evidence of an enhancement of the front propagation speed (with respect to the laminar case), providing a phenomenological argument to explain the observed behaviour. When the reaction is very fast, instead, the formation of sharp fronts separating patches of pure phases, leads to an increase of intermittency in the small scale statistics of the temperature field.

Originele taal-2	Engels
Titel	13th European Turbulence Conference (ETC13)
Pagina's	092024-1/10
DOI's	https://doi.org/10.1088/1742-6596/318/9/092024
Status	Gepubliceerd - 2011

Publicatie series

Naam	Journal of Physics: Conference Series
Volume	318
ISSN van geprinte versie	1742-6588

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10.1088/1742-6596/318/9/092024

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@inproceedings{f7b2525a9daa4e0a8c84c642fd420187,

title = "Front propagation in Rayleigh-Taylor systems with reaction",

abstract = "A special feature of Rayleigh-Taylor systems with chemical reactions is the competition between turbulent mixing and the {"}burning processes{"}, which leads to a highly non-trivial dynamics. We studied the problem performing high resolution numerical simulations of a 2d system, using a thermal lattice Boltzmann (LB) model. We spanned the various regimes emerging at changing the relative chemical/turbulent time scales, from slow to fast reaction; in the former case we found numerical evidence of an enhancement of the front propagation speed (with respect to the laminar case), providing a phenomenological argument to explain the observed behaviour. When the reaction is very fast, instead, the formation of sharp fronts separating patches of pure phases, leads to an increase of intermittency in the small scale statistics of the temperature field.",

author = "Andrea Scagliarini and L. Biferale and F. Mantovani and M. Pivanti and F. Pozzati and M. Sbragaglia and S.F. Schifano and F. Toschi and R. Tripicionne",

year = "2011",

doi = "10.1088/1742-6596/318/9/092024",

language = "English",

series = "Journal of Physics: Conference Series",

pages = "092024--1/10",

booktitle = "13th European Turbulence Conference (ETC13)",

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TY - GEN

T1 - Front propagation in Rayleigh-Taylor systems with reaction

AU - Scagliarini, Andrea

AU - Biferale, L.

AU - Mantovani, F.

AU - Pivanti, M.

AU - Pozzati, F.

AU - Sbragaglia, M.

AU - Schifano, S.F.

AU - Toschi, F.

AU - Tripicionne, R.

PY - 2011

Y1 - 2011

N2 - A special feature of Rayleigh-Taylor systems with chemical reactions is the competition between turbulent mixing and the "burning processes", which leads to a highly non-trivial dynamics. We studied the problem performing high resolution numerical simulations of a 2d system, using a thermal lattice Boltzmann (LB) model. We spanned the various regimes emerging at changing the relative chemical/turbulent time scales, from slow to fast reaction; in the former case we found numerical evidence of an enhancement of the front propagation speed (with respect to the laminar case), providing a phenomenological argument to explain the observed behaviour. When the reaction is very fast, instead, the formation of sharp fronts separating patches of pure phases, leads to an increase of intermittency in the small scale statistics of the temperature field.

AB - A special feature of Rayleigh-Taylor systems with chemical reactions is the competition between turbulent mixing and the "burning processes", which leads to a highly non-trivial dynamics. We studied the problem performing high resolution numerical simulations of a 2d system, using a thermal lattice Boltzmann (LB) model. We spanned the various regimes emerging at changing the relative chemical/turbulent time scales, from slow to fast reaction; in the former case we found numerical evidence of an enhancement of the front propagation speed (with respect to the laminar case), providing a phenomenological argument to explain the observed behaviour. When the reaction is very fast, instead, the formation of sharp fronts separating patches of pure phases, leads to an increase of intermittency in the small scale statistics of the temperature field.

U2 - 10.1088/1742-6596/318/9/092024

DO - 10.1088/1742-6596/318/9/092024

M3 - Conference contribution

T3 - Journal of Physics: Conference Series

SP - 092024-1/10

BT - 13th European Turbulence Conference (ETC13)

ER -

Front propagation in Rayleigh-Taylor systems with reaction

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