Drag Crisis in Fractal Trees Revealed by Simulation and Theory
Abstract
Trees are key roughness elements in urban environments, shaping airflow, microclimates, and pollutant dispersion. Yet the aerodynamic drag of complex tree-like structures at high Reynolds numbers remains poorly characterized compared with the well-studied drag crisis of simple bluff bodies. We combine large-scale lattice Boltzmann simulations with an analytical branch-wise drag model to examine fractal trees over a wide range of height-based Reynolds numbers, ReH. Direct numerical simulations using a cumulant lattice Boltzmann method with adaptive mesh refinement cover 2.5×103 ReH 1.2×105, and the analytical model extends predictions to ReH 109. Under uniform inflow, the analysis indicates a drag-crisis transition near ReH ≈ 3×106, with increasing structural complexity smoothing this transition because smaller branches remain subcritical. Introducing inflow turbulence with streamwise intensity Iu ≈ 8\%, representative of atmospheric-boundary-layer winds, shifts the apparent onset to ReH ≈ 1.5×105 and further moderates the drag reduction. Interpreted at full scale, this suggests that urban trees of order 10--30 m exposed to winds of 1--10~m/s generally operate in the crisis or post-crisis regime. In both uniform and turbulent inflow, the framework predicts a reversal in drag-coefficient ordering across geometries: simplified trees show lower drag in the subcritical regime but may exhibit higher drag in the supercritical regime, whereas more complex trees undergo a smoother, moderated crisis. These results challenge the common assumption that pruning always reduces aerodynamic loading and highlight the need to reassess vegetation-drag parameterizations and pruning strategies in high-ReH conditions.
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