Large-eddy simulation of sand transport under unsteady wind.

Aeolian sand movement contributes to evolution of surface landforms on Earth and Mars, as well as on Venus and Titan. Most natural landforms in arid regions are molded by wind with a general feature of unsteadiness. Many researches have improved our cognition of saltation in unsteady flow, but it is probably true that this issue is not yet fully analysed. In this paper, we conducted three-dimensional numerical simulations of wind-blown sand under unsteady wind conditions. The trajectories of sand particles are simulated by using a Lagrangian model. Particle motion, particle-bed interaction and wind modification have been taken into account. Results indicate that the characteristics of sand transport in unsteady and steady wind conditions profoundly differ; the sediment transport in unsteady conditions is significantly enhanced and increases with the amplitude of the sinusoidal wind fluctuations; the time series of sediment transport reveals a sine-like variation which lags behind the variation of the wind with a time delay of about 1 s (response time of saltation to wind variation). In unsteady conditions, sand transport shows an 'overshoot' which is embodied in the initial wave of the sediment transport. The impact of unsteady sediment transport should be paid more attention in future Aeolian research. Our work undertakes the key point by conducting three-dimensional numerical simulation of solid particles over unsteady wind conditions. Corresponding to different amplitudes and frequencies, the sediment transport rate reveals a sine-like variation, and the average sediment transport rate of unsteady flow is greater than that of uniform one. Unlabelled Image • 3D numerical simulations of wind-blown sand under unsteady wind are conducted in terms of LES. • Characteristics of unsteady wind have an impact on sediment transport and particle velocity. • The first wave crest of sediment transport is affected by wind period. [ABSTRACT FROM AUTHOR]