A hydrodynamical theory of conservative bounded density currents

M. W. Moncrieff; D. W. K. So

doi:10.1017/S0022112089000091

Abstract

The Benjamin (1968) analysis of a two-fluid density current is extended to include the effect of vorticity within the current. In the case of constant vorticity, the density-current depth is shown to lie between the limits of half and two-thirds of the channel depth. More general vorticity distributions are also considered, namely those that have: (i) a maximum in the upper and lower regions of the density current; and (ii) a maximum in the middle of the density current. In the former, as in the case of constant vorticity, density-current structures exist, whereas in the latter, deep overturning circulations predominate which can cause a ‘blocking’ of the upstream inflow. A generalized propagation formula which includes the effects of finite depth and rear inflow into the density current is established and the uniqueness issue is considered.

The analysis is further extended to a three-fluid system, composed of physically distinct component flows, namely, a density current, an overturning updraught region in upper levels ahead of the density current and an updraught in which the fluid ascends without overturning to its outflow level. Two types of behaviour are identified. First, a symmetric mode in which the density current and the overturning updraught have the same depth and, second, an asymmetric mode with solutions restricted to a certain parameter range. A special case in which the fluids have the same density illustrates the basic dynamics of the problem and also the nature of the vertical transport of momentum.

References

Benjamin, T. B.: 1968 Gravity currents and related phenomena. J. Fluid Mech. 31, 209–248.Google Scholar

Britter, R. E. & Simpson, J. E., 1978 Experiments on the dynamics of a gravity current head. J. Fluid Mech. 88, 223–240.Google Scholar

Crook, N. A. & Miller, M. J., 1985 A numerical and analytical study of atmospheric undular bores. Q. J. R. Met. Soc. 111, 225–242.Google Scholar

Holyer, J. Y. & Huppert, H. E., 1980 Gravity currents entering a two-layer fluid. J. Fluid Mech. 100, 739–767.Google Scholar

von Kármán, T.1940 The engineer grapples with non-linear problems. Bull. Am. Math. Soc. 46, 615–683.Google Scholar

Moncrieff, M. W.: 1978 The dynamical structure of two-dimensional steady convection in constant vertical shear. Q. J. R. Met. Soc. 104, 563–567.Google Scholar

Moncrieff, M. W.: 1981 A theory of organised steady convection and its transport properties. Q. J. R. Soc. 107, 29–50.Google Scholar

Moncrieff, M. W.: 1988 Analytical models of narrow cold frontal rainbands and related phenomena. J. Atmos. Sci. (in press).Google Scholar

Simpson, J. E.: 1969 A comparison between laboratory and atmospheric density currents. Q. J. R. Met Soc. 95, 758–765.Google Scholar

Simpson, J. E.: 1982 Gravity currents in the laboratory, atmosphere and ocean. Ann. Rev. Fluid Mech. 14, 213–234.Google Scholar

Wallis, G. B. & Dobson, J. E., 1973 The onset of slugging in horizontal stratified air-water flow. Intl J. Multiphase Flow 1, 173–193.Google Scholar

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Moncrieff, Mitchell W. 1992. Organized Convective Systems: Archetypal Dynamical Models, Mass and Momentum Flux Theory, and Parametrization. Quarterly Journal of the Royal Meteorological Society, Vol. 118, Issue. 507, p. 819.

Lemaitre, Y. and Scialom, G. 1992. Three‐Dimensional Mesoscale Circulation Within A Convective Post‐Frontal System. Possible Role of Conditional Symmetric Instability For Triggering Convective Motion. Quarterly Journal of the Royal Meteorological Society, Vol. 118, Issue. 503, p. 71.

Garner, S. T. and Thorpe, A. J. 1992. The Development of Organized Convection In A Simplified Squall‐Line Model. Quarterly Journal of the Royal Meteorological Society, Vol. 118, Issue. 503, p. 101.

Kanehisa, Hirotada 1995. A Note on Gravity Waves Associated with a Density Current. Journal of the Meteorological Society of Japan. Ser. II, Vol. 73, Issue. 6, p. 1161.

Moncrieff, Mitchell W. 1997. The Physics and Parameterization of Moist Atmospheric Convection. p. 231.

Garstang, M. White, S. Shugart, H. H. and Halverson, J. 1998. Convective cloud downdrafts as the cause of large blowdowns in the Amazon rainforest. Meteorology and Atmospheric Physics, Vol. 67, Issue. 1-4, p. 199.

Lemaǐtre, Y. Scialom, G. and Protat, A. 2001. Conditional symmetric instability, frontogenetic forcing and rain‐band organization. Quarterly Journal of the Royal Meteorological Society, Vol. 127, Issue. 578, p. 2599.

Xue, Ming 2002. Density currents in shear flows: Effects of rigid lid and cold‐pool internal circulation, and application to squall line dynamics. Quarterly Journal of the Royal Meteorological Society, Vol. 128, Issue. 579, p. 47.

Trier, S. B. Davis, C. A. Ahijevych, D. A. Weisman, M. L. and Bryan, G. H. 2006. Mechanisms Supporting Long-Lived Episodes of Propagating Nocturnal Convection within a 7-Day WRF Model Simulation. Journal of the Atmospheric Sciences, Vol. 63, Issue. 10, p. 2437.

Stechmann, Samuel N. Majda, Andrew J. and Khouider, Boualem 2008. Nonlinear dynamics of hydrostatic internal gravity waves. Theoretical and Computational Fluid Dynamics, Vol. 22, Issue. 6, p. 407.

Tao, Wei‐Kuo and Moncrieff, Mitchell W. 2009. Multiscale cloud system modeling. Reviews of Geophysics, Vol. 47, Issue. 4,

Grandpeix, Jean-Yves and Lafore, Jean-Philippe 2010. A Density Current Parameterization Coupled with Emanuel’s Convection Scheme. Part I: The Models. Journal of the Atmospheric Sciences, Vol. 67, Issue. 4, p. 881.

Moncrieff, Mitchell W. 2010. Climate Dynamics: Why Does Climate Vary?. Vol. 189, Issue. , p. 3.

Lafore, J.‐P. Flamant, C. Giraud, V. Guichard, F. Knippertz, P. Mahfouf, J.‐F. Mascart, P. and Williams, E.R. 2010. Introduction to the AMMA Special Issue on ‘Advances in understanding atmospheric processes over West Africa through the AMMA field campaign’. Quarterly Journal of the Royal Meteorological Society, Vol. 136, Issue. S1, p. 2.

Dalu, Giovanni A. and Baldi, Marina 2010. Steady-State Dynamics of a Density Current in an f-Plane Nonlinear Shallow-Water Model. Journal of the Atmospheric Sciences, Vol. 67, Issue. 2, p. 500.

Lane, Todd P. and Moncrieff, Mitchell W. 2015. Long-Lived Mesoscale Systems in a Low–Convective Inhibition Environment. Part I: Upshear Propagation. Journal of the Atmospheric Sciences, Vol. 72, Issue. 11, p. 4297.

Moncrieff, Mitchell W. and Lane, Todd P. 2015. Long-Lived Mesoscale Systems in a Low–Convective Inhibition Environment. Part II: Downshear Propagation. Journal of the Atmospheric Sciences, Vol. 72, Issue. 11, p. 4319.

Yano, Jun-Ichi and Moncrieff, Mitchell W. 2016. Numerical Archetypal Parameterization for Mesoscale Convective Systems. Journal of the Atmospheric Sciences, Vol. 73, Issue. 7, p. 2585.

Meyer, Bettina and Haerter, Jan O. 2020. Mechanical Forcing of Convection by Cold Pools: Collisions and Energy Scaling. Journal of Advances in Modeling Earth Systems, Vol. 12, Issue. 11,

Lamaakel, Oumaima and Matheou, Georgios 2022. Organization Development in Precipitating Shallow Cumulus Convection: Evolution of Turbulence Characteristics. Journal of the Atmospheric Sciences, Vol. 79, Issue. 9, p. 2419.

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A hydrodynamical theory of conservative bounded density currents

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This article has been cited by the following publications. This list is generated based on data provided by Crossref.

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