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Aerosol-induced changes in the vertical structure of precipitation: a perspective of TRMM precipitation radar
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Journal Article
Aerosol-induced changes in the vertical structure of precipitation: a perspective of TRMM precipitation radar
2018
Overview
Our knowledge is still poor regarding the response of the precipitation vertical
structure to aerosols, partly due to the ignorance of precipitation occurring
at different spatial scales. A total of 6 years of collocated ground-based PM10
and satellite-based (Tropical Rainfall Measuring Mission, TRMM) radar data, along with ERA-Interim reanalysis, are
used in this study to investigate the aerosol effects on three localized rain
regimes (shallow, stratiform, and convective rain) over the Pearl River Delta
region of China. A subjective analysis method is proposed to discriminate
between the localized and synoptic-scale precipitations based on weather
composite charts where daily averaged wind field at 850 hPa is overlaid with
the geopotential height at 500 hPa. In general, average rain rate tends to be
greater under polluted conditions than under clean conditions. But such
potential aerosol effects are regime dependent: as the atmosphere becomes
slightly polluted (PM10≤38 µg m−3), the top 1 % radar reflectivity (Z) for all regimes
initially increases, followed by continued increases and weak decreases for
convective and stratiform/shallow rain regimes, respectively. As the
atmosphere becomes much more polluted, such regime dependences of aerosol
effects are more significant. From a perspective of the vertical Z structure,
comparisons between polluted conditions (days with the highest third of
PM10 concentration) and clean conditions (days with the lowest third of
PM10 concentration) show that the convective rain regime exhibits a deeper
and stronger Z pattern, whereas a much shallower and weaker Z pattern is
observed for stratiform and shallow precipitation regimes. In particular, the
top height of the 30 dBZ rain echo increases by ∼29 %
(∼1.27 km) for the convective regime, but decreases by
∼10.8 % (∼0.47 km) for the stratiform regime.
However, no noticeable changes are observed for the shallow precipitation regime.
Impacts of meteorological factors are further studied on both rain top height
(RTH) and the center of gravity of Z, including vertical velocity, vertical wind
shear, convection available potential energy, and vertically integrated
moisture flux divergence (MFD). The possible invigoration effect on convective
precipitation seems dependent on wind shear, in good agreement with previous
findings. Overall, the observed dependence of the precipitation vertical
structure on ground-based PM10 supports the notion of aerosol
invigoration or suppression effect on cold or warm rain and adds new insights into
the nature of the complex interactions between aerosol and various localized
precipitation regimes.
