posted on 2016-08-08, 00:00authored byChen Cai, Rachael E. H. Miles, Michael
I. Cotterell, Aleksandra Marsh, Grazia Rovelli, Andrew M. J. Rickards, Yun-hong Zhang, Jonathan P. Reid
Representing
the physicochemical properties of aerosol particles
of complex composition is of crucial importance for understanding
and predicting aerosol thermodynamic, kinetic, and optical properties
and processes and for interpreting and comparing analysis methods.
Here, we consider the representations of the density and refractive
index of aqueous–organic aerosol with a particular focus on
the dependence of these properties on relative humidity and water
content, including an examination of the properties of solution aerosol
droplets existing at supersaturated solute concentrations. Using bulk
phase measurements of density and refractive index for typical organic
aerosol components, we provide robust approaches for the estimation
of these properties for aerosol at any intermediate composition between
pure water and pure solute. Approximately 70 compounds are considered,
including mono-, di- and tricarboxylic acids, alcohols, diols, nitriles,
sulfoxides, amides, ethers, sugars, amino acids, aminium sulfates,
and polyols. We conclude that the molar refraction mixing rule should
be used to predict the refractive index of the solution using a density
treatment that assumes ideal mixing or, preferably, a polynomial dependence
on the square root of the mass fraction of solute, depending on the
solubility limit of the organic component. Although the uncertainties
in the density and refractive index predictions depend on the range
of subsaturated compositional data available for each compound, typical
errors for estimating the solution density and refractive index are
less than ±0.1% and ±0.05%, respectively. Owing to the direct
connection between molar refraction and the molecular polarizability,
along with the availability of group contribution models for predicting
molecular polarizability for organic species, our rigorous testing
of the molar refraction mixing rule provides a route to predicting
refractive indices for aqueous solutions containing organic molecules
of arbitrary structure.