Abstract. Below-cloud wet scavenging is an important pathway to remove atmospheric aerosols. The below-cloud wet scavenging coefficient (BWSC) is the value to describe the ability of rainfall to remove aerosols. The reported BWSCs obtained from the field measurements are much higher than the theory, but the reason for this remains unclear. In this study, based on the long-term field measurements in the Yangtze River Delta of eastern China, we find 28 % of the rainfall events are high BWSC events. The high BWSC events show the sudden decrease of particle number concentration in all size bins near the end of rainfall. By investigating the circulation patterns, backward trajectories and the variations of simultaneously observed atmospheric components, we find the cause of the high BWSC events is the air masses changing but not the wet scavenging. The change of air masses is always followed by the rainfall processes and cannot be screened out by the traditional meteorological criteria, which would cause the overestimation of BWSC. After excluding the high BWSC events, the observed BWSC is close to the theory and is correlated with the rainfall intensity and particle number concentrations prior to rainfall. This study highlights the discrepancy between the observed BWSC and the theoretical value may not be as large as it is currently believed. To obtain reasonable BWSCs and parameterization from field measurements, the effect of air masses changing during rainfall needs to be carefully considered.
Abstract. Below-cloud wet scavenging is an important pathway to
remove atmospheric aerosols. The below-cloud wet-scavenging coefficient
(BWSC) is the value to describe the ability of rainfall to remove aerosols.
The reported BWSCs obtained from the field measurements are much higher than
the theory, but the reason for this remains unclear. Based on the long-term
field measurements in the Yangtze River Delta of eastern China, we find that
28 % of the rainfall events are high-BWSC events. The high-BWSC events
show the sudden decrease in the particle number concentration in all size bins
near the end of rainfall. By investigating the simultaneously observed
changes in carbon monoxide and aerosol chemical compositions during rainfall
events, the circulation patterns, and backward trajectories, we find the
cause of the high-BWSC events is the air mass changing but not the wet
scavenging. The change in air masses is always followed by the rainfall
processes and cannot be screened out by the traditional meteorological
criteria, which would cause the overestimation of BWSC. After excluding the
high-BWSC events, the observed BWSC is close to the theory and is correlated
with the rainfall intensity and particle number concentrations prior to
rainfall. This study highlights that the discrepancy between the observed
BWSC and the theoretical value may not be as large as is currently
believed. To obtain reasonable BWSCs and parameterization from field
measurements, the effect of air mass changing during rainfall needs to be
carefully considered.
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