Optical Properties and Refractive Index of Wintertime Aerosol at a Highly Polluted North‐Indian Site

Estimation of aerosol radiative forcing continues to suffer from large uncertainties, partially from a lack of observations of aerosol optical properties. Limited measurements of the atmospheric aerosol imaginary refractive index (iRI) have been made, especially in some of the world's most poll...

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Bibliographic Details
Published in:Journal of geophysical research. Atmospheres 2023-07, Vol.128 (14), p.n/a
Main Authors: Kapoor, Taveen Singh, Phuleria, Harish C., Sumlin, Benjamin, Shetty, Nishit, Anurag, Gupta, Bansal, Mahak, Duhan, Sandeep Singh, Khan, Mohd Shahzar, Laura, Jitender Singh, Manwani, Pooja, Chakrabarty, Rajan K., Venkataraman, Chandra
Format: Article
Language:English
Subjects:
absorbing aerosol
Absorption
Aerosol absorption
Aerosol effects
Aerosol optical properties
aerosol optics
Aerosols
Albedo
Atmosphere
Atmospheric absorption
Atmospheric aerosols
Atmospheric models
Biomass burning
black carbon
brown carbon
Carbon
Carbon sources
Chemical properties
Chemicophysical properties
Climate
Climate models
Climatic indexes
Combustion
Complex numbers
Diameters
Emissions
Fossil fuels
Geophysics
Material properties
Modelling
Optical properties
Optimization
Organic carbon
Parameter sensitivity
Particulate matter
Physical properties
Radiative forcing
Refractive index
Refractivity
Scattering
Sensitivity analysis
Simulation
Sunlight
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Summary:Estimation of aerosol radiative forcing continues to suffer from large uncertainties, partially from a lack of observations of aerosol optical properties. Limited measurements of the atmospheric aerosol imaginary refractive index (iRI) have been made, especially in some of the world's most polluted regions. In this study, we measured aerosol optical and micro‐physical properties at a regional site, Rohtak, India, representative of polluted cities in the Indo‐Gangetic plains in northern India. The average PM2.5 measured during the campaign was 163 μg/m3 with a single‐scatter albedo of 0.7, indicating the presence of strongly absorbing aerosol components. Measurements of aerosol absorption, scattering, and particle number size distributions were used to estimate the effective refractive index using an established Mie inversion technique. The calculated iRI was spectrally invariant in the visible region with values ranging between 0.076 and 0.145. Brown carbon absorption, estimated using an existing Mie optimization method, ranged 34–88 Mm−1, with strongly absorbing mass absorption cross‐sections (∼1.9 m2/g). Higher iRI were observed during periods with higher brown carbon absorption, which are likely directly emitted from combustion sources. Low volatility organic carbon fractions dominated during these periods, with likely persistence of atmospheric absorption. The iRI values are at the upper end of previously reported ranges of urban aerosol iRI. In a sensitivity analysis to measured parameters, the absorption had the dominant effect on estimated iRI. Measured single scatter albedos, were lower than those from climate model simulations over the region, demonstrating the need for intrinsic property measurements to evaluate and constrain climate models. Plain Language Summary Particles in the atmosphere, called aerosol, can absorb or reflect/scatter sunlight to heat or cool the atmosphere, depending upon their physical and chemical properties. Climate models try to simulate these properties to understand their effect on the climate. The strength of the absorption is determined by the size of the particle (generally the diameter) and its refractive index (a complex number) which is a material property. In this study, we measure the refractive index of atmospheric aerosol at Rohtak, which lies in the highly polluted Indo‐Gangetic plains in India. We find that the aerosol are very absorbing in nature, that is, they are warming the atmosphere, and that the absor
ISSN:2169-897X
2169-8996
DOI:10.1029/2022JD038272