H. van Dop scite author profile

First a small time analysis is developed for the first and second moments of the velocity (W) and displacement (Z) in one direction of particles marked at a given point in an inhomogeneous unsteady turbulent flow, in terms of the local energy dissipation rate, and the local derivatives of the second and third moments of the vertical component of the velocity field, ∂∼(u23)/∂z and ∼(∂u33)/∂z. Then the appropriate form of a Langevin equation in inhomogeneous turbulence is suggested, namely, dW=(−W/TL+a1)dt+a1/22 dωt where a1, a2, and TL are functions of the particle position and time, and dωt is a random Gaussian velocity increment with ∼(dωt)=0 and ∼((dωt))2=dt. For simplicity, only one component of the particle motion, W(t), is considered. The functions a1 and a2 are determined by relating the random walk model to the Eulerian conservation equations for the mass of the contaminant and volume of the flow (i.e., the continuity equation), using the Fokker–Planck equation and the Eulerian equations for the moments of a vertical velocity. The coefficients a1 and a2 reduce to the same form as that obtained by the statistical analysis, namely a1=∂∼(u23)/∂z, (≊dW̄/dt, when t → 0) and a2=2∼(u23)/TL +d∼(u23)/dt (≊2∼(W′2)/TL+d∼(W′2)/dt, when t → 0). It is shown that the random walk model has the correct behavior as t/TL → 0. The theory is shown to agree reasonably well with the measurements of mean height and mean vertical displacement of particles released in a convective boundary layer [Q. J. R. Meteorol. Soc. 102, 427 (1976)]. Yaglom’s [Isv. Atmos. Oceanic Phys. 8, 333 (1972)] surface similarity result is recovered as a special case. For t ≫ TL, and in a zero-skewness steady turbulence, the random walk model reduces to the familiar K-diffusion equation. Some examples are presented to show that mean and mean square particle displacements from the random walk model are virtually identical to those obtained from the analytical solution of the corresponding Eulerian moment equations. Careful analysis is still required when concentration distributions in turbulent flows near a boundary are evaluated using random walk models.

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Turbulent mixing and the chemical breakdown of isoprene in the atmospheric boundary layer

Verver¹,

Dop²,

Holtslag³

2000

J. Geophys. Res.

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Photochemical production of ozone in Western Europe (1971–1975) and its relation to meteorology

Guicherit¹,

Dop

1977

Atmospheric Environment (1967)

145

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Turbulent mixing of reactive gases in the convective boundary layer

Verver

Dop

Holtslag

1997

Boundary-Layer Meteorology

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Large-eddy simulation of katabatic winds. Part 1: Comparison with observations

Axelsen

Dop

2009

Acta Geophys.

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H. van Dop

Random walk models for particle displacements in inhomogeneous unsteady turbulent flows

Turbulent mixing and the chemical breakdown of isoprene in the atmospheric boundary layer

Photochemical production of ozone in Western Europe (1971–1975) and its relation to meteorology

Turbulent mixing of reactive gases in the convective boundary layer

Large-eddy simulation of katabatic winds. Part 1: Comparison with observations

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