Seasonal contrast in size distributions and mixing state of black carbon and its association with PM&amp;lt;sub&amp;gt;1.0&amp;lt;/sub&amp;gt; chemical composition from the eastern coast of India

Kompalli, Sobhan Kumar; Satheesh, S. K.; Moorthy, K. Krishna; Das, Trupti; Boopathy, R.; Liu, Dantong; Darbyshire, Eoghan; Allan, J. D.; Brooks, James; Flynn, Michael J.; Coe, Hugh

doi:10.5194/acp-20-3965-2020

Cited by 44 publications

(31 citation statements)

References 80 publications

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“…Recently, Ko et al (2020) compared the MMD and NMD values of rBC size distributions from different dominant sources. Previous studies report that the MMD (and NMD) values over the regions dominated by fresh fossil fuel emissions are smaller (MMD ∼ 100 to 178 nm and NMD ∼ 30 to 80 nm) compared to the areas with dominant solid-fuel sources (biomass, biofuel, coal-burning) (MMD ∼ 130 to 210 nm and NMD ∼ 100 to 140 nm), whereas well-aged and background BC particles in outflow regions have MMD values in between (MMD ∼ 180 to 225 nm and NMD ∼ 90 to 120 nm) (McMeeking et al, 2010;Liu et al, 2010Liu et al, , 2014Kondo et al, 2011;Cappa et al, 2012;Sahu et al, 2012;Metcalf et al, 2012;Laborde et al, 2013;Reddington et al, 2013;Gong et al, 2016;Raatikainen et al, 2017;Krasowsky et al, 2018;Brooks et al, 2019;Kompalli et al, 2020b;Ko et al, 2020). The spatial distribution of mass median diameter and number median diameters during the ICARB-2018 shown in Fig.…”

Section: Spatial Distribution Of Rbc Mass/number Concentrations and Size Distributionsmentioning

confidence: 99%

Mixing state of refractory black carbon aerosol in the South Asian outflow over the northern Indian Ocean during winter

et al. 2021

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Abstract. Regional climatic implications of aerosol black carbon (BC), which has a wide variety of anthropogenic sources in large abundance, are well recognized over South Asia. Significant uncertainties remain in its quantification due to a lack of sufficient information on the microphysical properties (its concentration, size, and mixing state with other aerosol components) that determine the absorption potential of BC. In particular, the information on the mixing state of BC is extremely sparse over this region. In this study, the first observations of the size distribution and mixing state of individual refractory black carbon (rBC) particles in the South Asian outflow to the south-eastern Arabian Sea and the northern and equatorial Indian Ocean regions are presented based on measurements using a single particle soot photometer (SP2) aboard the Integrated Campaign for Aerosols, gases, and Radiation Budget (ICARB-2018) ship during winter 2018 (16 January to 13 February). The results revealed significant spatial heterogeneity of BC characteristics. The highest rBC mass concentrations (∼938±293 ng m−3) with the highest relative coating thickness (RCT; the ratio of BC core to its coating diameters) of ∼2.16±0.19 are found over the south-east Arabian Sea (SEAS) region, which is in the proximity of the continental outflow. As we move to farther oceanic regions, though the mass concentrations decreased by nearly half (∼546±80 ng m−3), BC still remained thickly coated (RCT∼2.05±0.07). The air over the remote equatorial Indian Ocean, which received considerable marine air masses compared to the other regions, showed the lowest rBC mass concentrations (∼206±114 ng m−3) with a moderately thick coating (RCT∼1.73±0.16). Even over oceanic regions far from the landmass, regions that received the outflow from the more industrialized east coast/the Bay of Bengal had a thicker coating (∼104 nm) compared to regions that received outflow from the west coast and/or peninsular India (∼86 nm). Although different regions of the ocean depicted contrasting concentrations and mixing state parameters due to the varied extent and nature of the continental outflow as well as the atmospheric lifetime of air masses, the modal parameters of rBC mass–size distributions (mean mass median diameters ∼ 0.19–0.20 µm) were similar over all regions. The mean fraction of BC-containing particles (FBC) varied in the range of 0.08–0.12 (suggesting significant amounts of non-BC particles), whereas the bulk mixing ratio of coating mass to rBC mass was highest (8.31±2.40) over the outflow regions compared to the remote ocean (4.24±1.45), highlighting the role of outflow in providing condensable material for coatings on rBC. These parameters, along with the information on the size-resolved mixing state of BC cores, throw light on the role of sources and secondary processing of their complex mixtures for coatings on BC under highly polluted conditions. Examination of the non-refractory sub-micrometre aerosol chemical composition obtained using the aerosol chemical speciation monitor (ACSM) suggested that the overall aerosol system was sulfate-dominated over the far-oceanic regions. In contrast, organics were equally prominent adjacent to the coastal landmass. An association between the BC mixing state and aerosol chemical composition suggested that sulfate was the probable dominant coating material on rBC cores.

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Section: Spatial Distribution Of Rbc Mass/number Concentrations and Size Distributionsmentioning

confidence: 99%

Mixing state of refractory black carbon aerosol in the South Asian outflow over the northern Indian Ocean during winter

et al. 2021

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“…It is well-known that EC is directly emitted into the atmosphere as fine particle via incomplete combustion of fossil fuel and biomass burning whereas coarse mode EC may be associated with adsorption of water molecule to the surface of EC particles or coating by organic/inorganic acids during their long-range transport in the atmosphere, leading to substantial increase in the particle diameter. 57 A robust correlation (0.96) was found between EC and nss-K + in fine mode, implying that biomass burning is a major source in fine mode. It is also worthy to note that EC was strongly correlated with OC in fine mode (0.90), however no such correlation was observed in the coarse mode (−0.02).…”

Section: Resultsmentioning

confidence: 89%

“…In contrast, EC showed unimodal during April 2018 and Sept. 2018 and bimodal size distributions during Nov. 2017, Jan. 2017, and March 2019, although the prominent peak was observed in fine mode. It is well-known that EC is directly emitted into the atmosphere as fine particle via incomplete combustion of fossil fuel and biomass burning whereas coarse mode EC may be associated with adsorption of water molecule to the surface of EC particles or coating by organic/inorganic acids during their long-range transport in the atmosphere, leading to substantial increase in the particle diameter . A robust correlation (0.96) was found between EC and nss-K + in fine mode, implying that biomass burning is a major source in fine mode.…”

Section: Resultsmentioning

confidence: 94%

Chemical Characteristics, Size Distributions, and Aerosol Liquid Water in Size-Resolved Coastal Urban Aerosols Allied with Distinct Air Masses over Tropical Peninsular India

Boreddy

Hegde

Aswini

2021

ACS Earth Space Chem.

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The present study reports on carbonaceous, water-soluble inorganic and organic components in size-resolved aerosols collected under different polluted air masses over a coastal urban location (Cochin) of tropical India. Results show that a high abundance of carbonaceous, non sea-salt (nss)-SO 4 2− , nss-K + , and NH 4 + in fine mode (<2 μm) is associated with northeasterly air masses, whereas sea-salts (Na + and Cl − ), NO 3 − , and nss-Ca 2+ were higher in coarse mode (>2.0 μm) aligned with northwesterly and southwest air masses. Organic carbon (OC) was characterized by a unimodal size distribution with a peak in fine mode during northeasterly and northwesterly air masses, whereas the peak was shifted to the coarse mode during southwest air masses. Elemental carbon (EC) showed unimodal size distribution during southwest air masses while bimodal distribution under northeasterly and northwesterly air masses with a prominent peak in fine mode was shown. NH 4 + , nss-SO 4 2− , nss-K + , and watersoluble OC (WSOC) showed unimodal size distributions with a peak in fine mode, whereas NO 3 − , sea-salts, and dust particles showed unimodal size distributions with a peak in the coarse mode. On the basis of these results together with correlation analysis and specific mass ratios, we emphasize that northeasterly air masses are highly enriched with secondary anthropogenic aerosols whereas primary coarse mode aerosols come from various sources such as sea-salts, dust, and NO x emissions linked with northwesterly and southwest air masses. The estimated aerosol−liquid−water (ALW) revealed that sea-salts, nitrate, and dust aerosols contribute to ALW in the coarse mode, whereas NH 4 + , SO 4 2− , and water-soluble organics are significantly important in fine mode aerosols.

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“…The association of BC with accumulation mode APs during continental conditions suggests that the carbonaceous APs existing in this size range can act as CCN. From the eastern coast of India, Kompalli et al (2020) have reported highly coated larger BC particles (> 110 nm) in dry conditions under the continental influence, while nascent BC particles (∼ 80 nm) with less coating were found during ISM due to wet scavenging. This finding is in line with the current marine-2 observations.…”

Section: Relationship Between Aerosol Absorption and Ccn Propertiesmentioning

confidence: 99%

Cloud condensation nuclei characteristics during the Indian summer monsoon over a rain-shadow region

et al. 2020

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Abstract. Continuous aerosol and cloud condensation nuclei (CCN) measurements carried out at the ground observational facility situated in the rain-shadow region of the Indian subcontinent are illustrated. These observations were part of the Cloud Aerosol Interaction Precipitation Enhancement Experiment (CAIPEEX) during the Indian summer monsoon season (June to September) of 2018. Observations are classified as dry–continental (monsoon break) and wet–marine (monsoon active) according to the air mass history. CCN concentrations measured for a range of supersaturations (0.2 %–1.2 %) are parameterized using Twomey's empirical relationship. CCN concentrations at low (0.2 %) supersaturation (SS) were high (>1000cm-3) during continental conditions and observed together with high black carbon (BC∼2000ngm-3) and columnar aerosol loading. During the marine air mass conditions, CCN concentrations diminished to ∼350cm-3 at 0.3 % SS and low aerosol loading persisted (BC∼800ngm-3). High CCN activation fraction (AF) of ≅0.55 (at 0.3 % SS) was observed before the monsoon rainfall, which reduced to ≅0.15 during the marine air mass and enhanced to ≅0.32 after that. There was mostly monomodal aerosol number size distribution (NSD) with a mean geometric mean diameter (GMD) of ≅85 nm, with least (≅9 %) contribution from nucleation mode (<30 nm) particles persisted before the monsoon, while multimode NSD with ≅19 % of nucleation mode particles was found during the marine air mass. Critical activation diameters (dcri) for 0.3 % SS were found to be about 72, 169, and 121 nm prior to, during, and after the marine conditions, respectively. The better association of CCN with aerosol absorption, and the concurrent accumulation mode particles during continental conditions, points to the possibility of aged (oxygenated) carbonaceous aerosols enhancing the CCN activity prior to the marine conditions. An enhancement in CCN concentrations and k values during the daytime along with absorption Ångström exponent was observed during the marine conditions. Best closure obtained using measured critical diameter and ammonium sulfate composition during continental conditions emphasizes the role of aged aerosols contributing to the accumulation mode, enhancing the CCN efficiency. The overestimation of CCN and less hygroscopicity of accumulation mode aerosols during the marine air mass indicate the role of size-dependent aerosol composition in CCN activity during the period.

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Seasonal contrast in size distributions and mixing state of black carbon and its association with PM<sub>1.0</sub> chemical composition from the eastern coast of India

Cited by 44 publications

References 80 publications

Mixing state of refractory black carbon aerosol in the South Asian outflow over the northern Indian Ocean during winter

Mixing state of refractory black carbon aerosol in the South Asian outflow over the northern Indian Ocean during winter

Chemical Characteristics, Size Distributions, and Aerosol Liquid Water in Size-Resolved Coastal Urban Aerosols Allied with Distinct Air Masses over Tropical Peninsular India

Cloud condensation nuclei characteristics during the Indian summer monsoon over a rain-shadow region

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