Abstract. The large-scale emissions of airborne
particulates from burning of agricultural residues particularly over the
upper Indo-Gangetic Plain (IGP) have often been associated with frequent
formation of haze, adverse health impacts, and modification in aerosol
climatology and thereby aerosol impact on regional climate. In this study,
short-term variations in aerosol climatology during extreme biomass burning
emissions over the IGP were investigated. Size-segregated particulate
concentration was initially measured and submicron particles (PM1.1)
were found to dominate particulate mass within the fine mode (PM2.1).
Particulate-bound water-soluble ions were mainly secondary in nature and
primarily composed of sulfate and nitrate. There was evidence of gaseous
NH3 dominating neutralization of acidic aerosol species
(SO42-) in submicron particles, in contrast to
crustal-dominating neutralization in coarser particulates. Diurnal variation
in black carbon (BC) mass ratio was primarily influenced by regional
meteorology, while gradual increase in BC concentration was consistent with
the increase in Delta-C, referring to biomass burning emissions. The
influence of biomass burning emissions was established using specific organic
(levoglucosan), inorganic (K+ and NH4+), and
satellite-based (UV aerosol index, UVAI) tracers. Levoglucosan was
the most abundant species within submicron particles (649±177 ng m−3), with a very high ratio (> 50) to other
anhydrosugars, indicating exclusive emissions from burning of agriculture
residues. Spatiotemporal distribution of aerosol and a few trace gases (CO
and NO2) was evaluated using both spaceborne active and passive
sensors. A significant increase in columnar aerosol loading (aerosol optical
depth, AOD: 0.98) was evident, with the presence of absorbing aerosols
(UVAI > 1.5) having low aerosol layer height (∼ 1.5 km).
A strong intraseasonality in the aerosol cross-sectional altitudinal profile
was even noted from CALIPSO, referring to the dominance of smoke and polluted
continental aerosols across the IGP. A possible transport mechanism of
biomass smoke was established using cluster analysis and
concentration-weighted air mass back trajectories. Short-wave aerosol
radiative forcing (ARF) was further simulated considering intraseasonality in
aerosol properties, which resulted in a considerable increase in atmospheric
ARF (135 W m−2) and heating rate (4.3 K day−1) during extreme
biomass burning emissions compared to the non-dominating period
(56 W m−2, 1.8 K day−1). Our analysis will be useful to improve
understanding of short-term variation in aerosol chemistry over the IGP and
to reduce uncertainties in regional aerosol–climate models.
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