Abstract
While the electrification of dust storms is known to substantially affect the lifting and transport of dust particles, the electrical structure of dust storms and its underlying charge separation mechanisms are largely unclear. Here we present an inversion method, which is based on the Tikhonov regularization for inverting the electric field data collected in a near-ground observation array, to reconstruct the space-charge density and electric field in dust storms. After verifying the stability, robustness, and accuracy of the inversion procedure, we find that the reconstructed space-charge density exhibits a universal three-dimensional mosaic pattern of oppositely charged regions, probably due to the charge separation by turbulence. Furthermore, there are significant linear relationships between the reconstructed space-charge densities and measured PM10 dust concentrations at each measurement point, suggesting a multi-point large-scale charge equilibrium phenomenon in dust storms. These findings refine our understanding of charge separation mechanisms and particle transport in dust storms.
Highlights
While the electrification of dust storms is known to substantially affect the lifting and transport of dust particles, the electrical structure of dust storms and its underlying charge separation mechanisms are largely unclear
More complicated electrical structures could arise in dust storms, which motivates us to develop a method for determining the structures of space-charge and electric field (E-field) in dust storms, both qualitatively and quantitatively
E-field data were collected at the Qingtu Lake Observation Array (QLOA), Gansu, China (Fig. 1a) between March 21 and June 2, 2017
Summary
While the electrification of dust storms is known to substantially affect the lifting and transport of dust particles, the electrical structure of dust storms and its underlying charge separation mechanisms are largely unclear. There are many examples of interest in disperse twophase flows, such as sand saltation[9,10,11,12,13,14], dust devils[15,16], dust and sand storms[17,18,19,20,21,22,23,24,25,26,27], blowing snows[28,29], thunderstorms[30], volcanic eruptions[31,32,33], fluidization beds[8,34], as well as dusty plasmas[2,35] In these systems, very intense electric field (E-field) and even lightning have been frequently observed due to particle electrification. More complicated electrical structures could arise in dust storms, which motivates us to develop a method for determining the structures of space-charge and E-field in dust storms, both qualitatively and quantitatively
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