Impacts of variations in aerosol refractive index on the retrieving of the light-absorption and hygroscopicity of ambient black carbon-containing aerosols using SP2

Abstract

Black carbon (BC) aerosols directly influence the earth's climate system by absorbing the light intensity and indirectly by interacting with clouds. The microphysical properties of BC-containing aerosols were determined by their core diameter and shell thickness, which can be derived from the measurement of a single-particle soot photometer (SP2). Traditionally, a constant real part of the shell's refractive index (RRI) was employed to retrieve the shell thickness of BC-containing aerosols using the measured scattering signals from SP2. Recent field measurements in East China show that ambient aerosol RRI varies over a wide range between 1.36 and 1.56. The influences of aerosol RRI variation on the retrieving of BC-containing aerosol shell thickness from the measurements of SP2 are investigated with simulation studies. Results show that the variation in ambient aerosol RRI can lead to a variation in the coating thickness of BC-containing aerosols by 9.4%. The corresponding uncertainties in the light absorption enhancement reach up to 29% due to the influence of aerosol RRI. The critical mean supersaturation (SS) of the BC-containing aerosol varies significantly between 0.044% and 0.055% due to the uncertainties in the derived shell thickness using a constant RRI. This study highlights the demand for the real-time measurement of ambient aerosol RRI when deriving the microphysical properties of ambient BC-containing aerosols from the SP2 measurement.