Particle clustering in radiation-induced turbulence

Rémi Zamansky; Filippo Coletti; Marc Massot; Ali Mani

Particle clustering in radiation-induced turbulence

Rémi Zamansky
, Filippo Coletti
, Marc Massot
, Ali Mani

Stanford University
Stanford University
Grande Voie des Vignes

Résultats de recherche: Contribution à une conférence › Papier › Revue par des pairs

Résumé

In the context of flows laden with inertial particles, we explore a novel regime, in which turbulence is sustained solely by the thermal radiation absorbed by the dispersed phase. When a fluid laden with particles is subject to radiative flux, non-uniformities in particle distribution result in local temperature fluctuations. Under the influence of gravity, buoyancy induces the vortical fluid motion leading to higher non-uniformities of inertial particles. From numerical simulations it is shown that the feedback loop between the local particle concentration, the temperature fluctuations and the convective motion can create and sustain turbulence. When the particle response time is comparable to the temporal scales of the flow, the system exhibits intense fluctuations of turbulent kinetic energy associated to the high intermittency of the particle concentration.

langue originale	Anglais
état	Publié - 1 janv. 2020
Modification externe	Oui
Evénement	14th European Turbulence Conference, ETC 2013 - Lyon, France Durée: 1 sept. 2013 → 4 sept. 2013

Une conférence

Une conférence	14th European Turbulence Conference, ETC 2013
Pays/Territoire	France
La ville	Lyon
période	1/09/13 → 4/09/13

Contient cette citation

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title = "Particle clustering in radiation-induced turbulence",

abstract = "In the context of flows laden with inertial particles, we explore a novel regime, in which turbulence is sustained solely by the thermal radiation absorbed by the dispersed phase. When a fluid laden with particles is subject to radiative flux, non-uniformities in particle distribution result in local temperature fluctuations. Under the influence of gravity, buoyancy induces the vortical fluid motion leading to higher non-uniformities of inertial particles. From numerical simulations it is shown that the feedback loop between the local particle concentration, the temperature fluctuations and the convective motion can create and sustain turbulence. When the particle response time is comparable to the temporal scales of the flow, the system exhibits intense fluctuations of turbulent kinetic energy associated to the high intermittency of the particle concentration.",

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TY - CONF

T1 - Particle clustering in radiation-induced turbulence

AU - Zamansky, Rémi

AU - Coletti, Filippo

AU - Massot, Marc

AU - Mani, Ali

PY - 2020/1/1

Y1 - 2020/1/1

N2 - In the context of flows laden with inertial particles, we explore a novel regime, in which turbulence is sustained solely by the thermal radiation absorbed by the dispersed phase. When a fluid laden with particles is subject to radiative flux, non-uniformities in particle distribution result in local temperature fluctuations. Under the influence of gravity, buoyancy induces the vortical fluid motion leading to higher non-uniformities of inertial particles. From numerical simulations it is shown that the feedback loop between the local particle concentration, the temperature fluctuations and the convective motion can create and sustain turbulence. When the particle response time is comparable to the temporal scales of the flow, the system exhibits intense fluctuations of turbulent kinetic energy associated to the high intermittency of the particle concentration.

AB - In the context of flows laden with inertial particles, we explore a novel regime, in which turbulence is sustained solely by the thermal radiation absorbed by the dispersed phase. When a fluid laden with particles is subject to radiative flux, non-uniformities in particle distribution result in local temperature fluctuations. Under the influence of gravity, buoyancy induces the vortical fluid motion leading to higher non-uniformities of inertial particles. From numerical simulations it is shown that the feedback loop between the local particle concentration, the temperature fluctuations and the convective motion can create and sustain turbulence. When the particle response time is comparable to the temporal scales of the flow, the system exhibits intense fluctuations of turbulent kinetic energy associated to the high intermittency of the particle concentration.

M3 - Paper

AN - SCOPUS:85085774482

T2 - 14th European Turbulence Conference, ETC 2013

Y2 - 1 September 2013 through 4 September 2013

ER -

Particle clustering in radiation-induced turbulence

Résumé

Une conférence

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