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Planetary Boundary Layer Height Modulates Aerosol—Water Vapor Interactions During Winter in the Megacity of Delhi
Date Issued
27-12-2021
Author(s)
S. Raj, Subha
Krüger, Ovid O.
Sharma, Amit
Panda, Upasana
Pöhlker, Christopher
Walter, David
Förster, Jan David
Singh, Rishi Pal
Swetha, S.
Klimach, Thomas
Darbyshire, Eoghan
Martin, Scot T.
McFiggans, Gordon
Coe, Hugh
Allan, James
Indian Institute of Technology, Madras
Soni, Vijay Kumar
Su, Hang
Andreae, Meinrat O.
Pöschl, Ulrich
Pöhlker, Mira L.
Indian Institute of Technology, Madras
Abstract
The Indo-Gangetic Plain (IGP) is one of the dominant sources of air pollution worldwide. During winter, the variations in planetary boundary layer (PBL) height, driven by a strong radiative thermal inversion, affect the regional air pollution dispersion. To date, measurements of aerosol-water vapor interactions, especially cloud condensation nuclei (CCN) activity, are limited in the Indian subcontinent, causing large uncertainties in radiative forcing estimates of aerosol-cloud interactions. We present the results of a one-month field campaign (February-March 2018) in the megacity, Delhi, a significant polluter in the IGP. We measured the composition of fine particulate matter (PM1) and size-resolved CCN properties over a wide range of water vapor supersaturations. The analysis includes PBL modeling, backward trajectories, receptor models and fire spots to elucidate the influence of PBL and air mass origins on aerosols. The aerosol properties depended strongly on PBL height and a simple power-law fit could parameterize the observed correlations of PM1 mass, aerosol particle number and CCN number with PBL height, indicating PBL induced changes in aerosol accumulation. The low inorganic mass fractions, low aerosol hygroscopicity and high externally mixed weakly CCN-active particles under low PBL height ((Formula presented.) 100 m) indicated the influence of PBL on aerosol aging processes. In contrast, aerosol properties did not depend strongly on air mass origins or wind direction, implying that the observed aerosol and CCN are from local emissions. An error function could parameterize the relationship between CCN number and supersaturation throughout the campaign.
Volume
126