Turbulent entrainment in a gravity current

M. Holzner; M. van Reeuwijk; H. Jonker

doi:10.1201/b21902-169

Turbulent entrainment in a gravity current

M. Holzner, M. van Reeuwijk, H. Jonker

Atmospheric Remote Sensing

Research output: Chapter in Book/Conference proceedings/Edited volume › Conference contribution › Scientific › peer-review

1 Citation (Scopus)

Abstract

We revisit the classical entrainment experiments for gravity currents on inclined slopes (Ellison and Turner, J. Fluid Mech. 6, 423-448, 1959). We derive an entrainment relation that couples the entrainment rate E to the production of turbulence kinetic energy, the net effect of buoyancy and inner layer. Using direct numerical simulations that are run for durations long enough for the flow to reach universal self-similarity, we show that the net effect of inner layer processes on entrainment is very small and that buoyancy has an almost negligible effect on E. It is demonstrated that the dominant process causing entrainment is turbulence production due to shear. Second, we observe that for all simulations the eddy diffusivity and dissipation rate can be parameterised using the turbulence kinetic energy and shear parameter. This information can be used to derive an entrainment law which is in good agreement with the Direct Numerical Simulation (DNS) results. We discuss the potential reasons for why this result is significantly different from experiments and the classical entrainment law introduced by Ellison and Turner.

Original language	English
Title of host publication	Sustainable Hydraulics in the Era of Global Change - Proceedings of the 4th European Congress of the International Association of Hydroenvironment engineering and Research, IAHR 2016
Editors	S. Erpicum, B. Dewals, P. Archambeau, M. Pirotton
Publisher	CRC Press / Balkema - Taylor & Francis Group
Pages	1025-1031
Number of pages	7
ISBN (Print)	978-113802977-4
DOIs	https://doi.org/10.1201/b21902-169
Publication status	Published - 2016
Event	4th European Congress of the International Association of Hydroenvironment engineering and Research, IAHR 2016 - Liege, Belgium Duration: 27 Jul 2016 → 29 Jul 2016

Conference

Conference	4th European Congress of the International Association of Hydroenvironment engineering and Research, IAHR 2016
Country/Territory	Belgium
City	Liege
Period	27/07/16 → 29/07/16

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Holzner, M., van Reeuwijk, M., & Jonker, H. (2016). Turbulent entrainment in a gravity current. In S. Erpicum, B. Dewals, P. Archambeau, & M. Pirotton (Eds.), Sustainable Hydraulics in the Era of Global Change - Proceedings of the 4th European Congress of the International Association of Hydroenvironment engineering and Research, IAHR 2016 (pp. 1025-1031). CRC Press / Balkema - Taylor & Francis Group. https://doi.org/10.1201/b21902-169

Holzner, M. ; van Reeuwijk, M. ; Jonker, H. / Turbulent entrainment in a gravity current. Sustainable Hydraulics in the Era of Global Change - Proceedings of the 4th European Congress of the International Association of Hydroenvironment engineering and Research, IAHR 2016. editor / S. Erpicum ; B. Dewals ; P. Archambeau ; M. Pirotton. CRC Press / Balkema - Taylor & Francis Group, 2016. pp. 1025-1031

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title = "Turbulent entrainment in a gravity current",

abstract = "We revisit the classical entrainment experiments for gravity currents on inclined slopes (Ellison and Turner, J. Fluid Mech. 6, 423-448, 1959). We derive an entrainment relation that couples the entrainment rate E to the production of turbulence kinetic energy, the net effect of buoyancy and inner layer. Using direct numerical simulations that are run for durations long enough for the flow to reach universal self-similarity, we show that the net effect of inner layer processes on entrainment is very small and that buoyancy has an almost negligible effect on E. It is demonstrated that the dominant process causing entrainment is turbulence production due to shear. Second, we observe that for all simulations the eddy diffusivity and dissipation rate can be parameterised using the turbulence kinetic energy and shear parameter. This information can be used to derive an entrainment law which is in good agreement with the Direct Numerical Simulation (DNS) results. We discuss the potential reasons for why this result is significantly different from experiments and the classical entrainment law introduced by Ellison and Turner.",

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Holzner, M, van Reeuwijk, M & Jonker, H 2016, Turbulent entrainment in a gravity current. in S Erpicum, B Dewals, P Archambeau & M Pirotton (eds), Sustainable Hydraulics in the Era of Global Change - Proceedings of the 4th European Congress of the International Association of Hydroenvironment engineering and Research, IAHR 2016. CRC Press / Balkema - Taylor & Francis Group, pp. 1025-1031, 4th European Congress of the International Association of Hydroenvironment engineering and Research, IAHR 2016, Liege, Belgium, 27/07/16. https://doi.org/10.1201/b21902-169

Turbulent entrainment in a gravity current. / Holzner, M.; van Reeuwijk, M.; Jonker, H.
Sustainable Hydraulics in the Era of Global Change - Proceedings of the 4th European Congress of the International Association of Hydroenvironment engineering and Research, IAHR 2016. ed. / S. Erpicum; B. Dewals; P. Archambeau; M. Pirotton. CRC Press / Balkema - Taylor & Francis Group, 2016. p. 1025-1031.

Research output: Chapter in Book/Conference proceedings/Edited volume › Conference contribution › Scientific › peer-review

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AU - van Reeuwijk, M.

AU - Jonker, H.

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N2 - We revisit the classical entrainment experiments for gravity currents on inclined slopes (Ellison and Turner, J. Fluid Mech. 6, 423-448, 1959). We derive an entrainment relation that couples the entrainment rate E to the production of turbulence kinetic energy, the net effect of buoyancy and inner layer. Using direct numerical simulations that are run for durations long enough for the flow to reach universal self-similarity, we show that the net effect of inner layer processes on entrainment is very small and that buoyancy has an almost negligible effect on E. It is demonstrated that the dominant process causing entrainment is turbulence production due to shear. Second, we observe that for all simulations the eddy diffusivity and dissipation rate can be parameterised using the turbulence kinetic energy and shear parameter. This information can be used to derive an entrainment law which is in good agreement with the Direct Numerical Simulation (DNS) results. We discuss the potential reasons for why this result is significantly different from experiments and the classical entrainment law introduced by Ellison and Turner.

AB - We revisit the classical entrainment experiments for gravity currents on inclined slopes (Ellison and Turner, J. Fluid Mech. 6, 423-448, 1959). We derive an entrainment relation that couples the entrainment rate E to the production of turbulence kinetic energy, the net effect of buoyancy and inner layer. Using direct numerical simulations that are run for durations long enough for the flow to reach universal self-similarity, we show that the net effect of inner layer processes on entrainment is very small and that buoyancy has an almost negligible effect on E. It is demonstrated that the dominant process causing entrainment is turbulence production due to shear. Second, we observe that for all simulations the eddy diffusivity and dissipation rate can be parameterised using the turbulence kinetic energy and shear parameter. This information can be used to derive an entrainment law which is in good agreement with the Direct Numerical Simulation (DNS) results. We discuss the potential reasons for why this result is significantly different from experiments and the classical entrainment law introduced by Ellison and Turner.

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BT - Sustainable Hydraulics in the Era of Global Change - Proceedings of the 4th European Congress of the International Association of Hydroenvironment engineering and Research, IAHR 2016

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Y2 - 27 July 2016 through 29 July 2016

ER -

Holzner M, van Reeuwijk M, Jonker H. Turbulent entrainment in a gravity current. In Erpicum S, Dewals B, Archambeau P, Pirotton M, editors, Sustainable Hydraulics in the Era of Global Change - Proceedings of the 4th European Congress of the International Association of Hydroenvironment engineering and Research, IAHR 2016. CRC Press / Balkema - Taylor & Francis Group. 2016. p. 1025-1031 doi: 10.1201/b21902-169

Turbulent entrainment in a gravity current

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