Turbulence, raindrops and the l(1/2) number density law

Abstract : Using a unique data set of three-dimensional drop positions and masses (the HYDROP experiment), we show that the distribution of liquid water in rain displays a sharp transition between large scales which follow a passive scalar-like Corrsin-Obukhov (k(-5/3)) spectrum and a small-scale statistically homogeneous white noise regime. We argue that the transition scale l(c) is the critical scale where the mean Stokes number (= drop inertial time/turbulent eddy time) St(l) is unity. For five storms, we found l(c) in the range 45-75 cm with the corresponding dissipation scale St(eta) in the range 200-300. Since the mean interdrop distance was significantly smaller (approximate to 10 cm) than l(c) we infer that rain consists of 'patches' whose mean liquid water content is determined by turbulence with each patch being statistically homogeneous. For l > l(c), we have St(l) < 1 and due to the observed statistical homogeneity for l < l(c), we argue that we can use Maxey's relations between drop and wind velocities at coarse grained resolution l(c). From this, we derive equations for the number and mass densities (n and rho) and their variance fluxes (psi and chi). By showing that chi is dissipated at small scales (with l(rho,diss) approximate to l(c)) and psi over a wide range, we conclude that rho should indeed follow Corrsin-Obukhov k(-5/3) spectra but that n should instead follow a k(-2) spectrum corresponding to fluctuations scaling as Delta rho proportional to l(1/3) and Delta n proportional to l(1/2). While the Corrsin-Obukhov law has never been observed in rain before, its discovery is perhaps not surprising; in contrast the Delta n approximate to l(1/2) number density law is quite new. The key difference between the Delta rho, Delta n laws is the fact that the microphysics (coalescence, breakup) conserves drop mass, but not numbers of particles. This implies that the timescale for the transfer of the density variance flux chi is determined by the strongly scale-dependent turbulent velocity whereas the timescale for the transfer of the number variance flux is determined by the weakly scale-dependent drop coalescence speed. We argue that the l(1/2) law may also hold (although in a slightly different form) for cloud drops. Because they are consequences of symmetries, we expect the l(1/3), l(1/2) laws to be robust. Since the large-scale turbulence determines the n and rho fields which are the 0th and 1st moments of the drop-size distribution, they constrain the microphysics: dimensional analysis shows that the cumulative probability distribution of nondimensional drop mass should be a universal function dependent only on scale; we confirm this empirically. The combination of number and mass density laws can be used to develop stochastic compound multifractal Poisson processes which are useful new tools for studying and modelling rain. We discuss the implications of this for the rain rate statistics including a simplified model, which can explain the observed rain rate spectra.
Type de document :
Article dans une revue
New Journal of Physics, Institute of Physics: Open Access Journals, 2008, 10, 〈10.1088/1367-2630/10/7/075017〉
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Soumis le : lundi 25 juin 2012 - 11:59:03
Dernière modification le : jeudi 22 mars 2018 - 22:34:50

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S. Lovejoy, D Schertzer. Turbulence, raindrops and the l(1/2) number density law. New Journal of Physics, Institute of Physics: Open Access Journals, 2008, 10, 〈10.1088/1367-2630/10/7/075017〉. 〈hal-00711540〉



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