Impact of non-ideality on reconstructing spatial and temporal variations in aerosol acidity with multiphase buffer theory

Abstract

Aerosol acidity is a key parameter in atmospheric aqueous chemistry and strongly influences the interactions of air pollutants and the ecosystem. The recently proposed multiphase buffer theory provides a framework to reconstruct long-term trends and spatial variations in aerosol pH based on the effective acid dissociation constant of ammonia (Ka,NH3-). However, non-ideality in aerosol droplets is a major challenge limiting its broad applications. Here, we introduced a non-ideality correction factor (cni) and investigated its governing factors. We found that besides relative humidity (RH) and temperature, cni is mainly determined by the molar fraction of NO3-in aqueous-phase anions, due to different NH4+ activity coefficients between (NH4)2SO4-and NH4NO3-dominated aerosols. A parameterization method is thus proposed to estimate cni at a given RH, temperature and NO3-fraction, and it is validated against long-term observations and global simulations. In the ammonia-buffered regime, with cni correction, the buffer theory can reproduce well the Ka,NH3-predicted by comprehensive thermodynamic models, with a root-mean-square deviation 0.1 and a correlation coefficient 1. Note that, while cni is needed to predict Ka,NH3-levels, it is usually not the dominant contributor to its variations, as 90% of the temporal or spatial variations in Ka,NH3-are due to variations in aerosol water and temperature.