Abstract
Abstract. The oxidation of SO2 to sulfate on sea salt aerosols in the marine environment is highly important because of its effect on the size distribution of sulfate and the potential for new particle nucleation from H2SO4 (g). However, models of the sulfur cycle are not currently able to account for the complex relationship between particle size, alkalinity, oxidation pathway and rate – which is critical as SO2 oxidation by O3 and Cl catalysis are limited by aerosol alkalinity, whereas oxidation by hypohalous acids and transition metal ions can continue at low pH once alkalinity is titrated. We have measured 34S/32S fractionation factors for SO2 oxidation in sea salt, pure water and NaOCl aerosol, as well as the pH dependency of fractionation. Oxidation of SO2 by NaOCl aerosol was extremely efficient, with a reactive uptake coefficient of ≈0.5, and produced sulfate that was enriched in 32S with αOCl = 0.9882±0.0036 at 19 °C. Oxidation on sea salt aerosol was much less efficient than on NaOCl aerosol, suggesting alkalinity was already exhausted on the short timescale of the experiments. Measurements at pH = 2.1 and 7.2 were used to calculate fractionation factors for each step from SO2(g) → multiple steps → SOOCl2−. Oxidation on sea salt aerosol resulted in a lower fractionation factor than expected for oxidation of SO32− by O3 (αseasalt = 1.0124±0.0017 at 19 °C). Comparison of the lower fractionation during oxidation on sea salt aerosol to the fractionation factor for high pH oxidation shows HOCl contributed 29% of S(IV) oxidation on sea salt in the short experimental timescale, highlighting the potential importance of hypohalous acids in the marine environment. The sulfur isotope fractionation factors measured in this study allow differentiation between the alkalinity-limited pathways – oxidation by O3 and by Cl catalysis (α34 = 1.0163±0.0018 at 19 °C in pure water or 1.0199±0.0024 at pH = 7.2) – which favour the heavy isotope, and the alkalinity non-limited pathways – oxidation by transition metal catalysis (α34 = 0.9905±0.0031 at 19 °C, Harris et al., 2012a) and by hypohalites (α34 = 0.9882±0.0036 at 19 °C) – which favour the light isotope. In combination with field measurements of the oxygen and sulfur isotopic composition of SO2 and sulfate, the fractionation factors presented in this paper may be capable of constraining the relative importance of different oxidation pathways in the marine boundary layer.
Highlights
1.1 The sulfur cycle in the marine boundary layerSea-salt aerosol is the dominant form of aerosol in the marine environment
Models of the sulfur cycle are not currently able to account for the complex relationship between particle size, alkalinity, oxidation pathway and rate – which is critical as SO2 oxidation by O3 and Cl catalysis are limited by aerosol alkalinity, whereas oxidation by hypohalous acids and transition metal ions can continue at low pH once alkalinity is titrated
This study presents measurements of 34S/32S fractionation during SO2 oxidation in sea salt aerosol and NaOCl aerosol, and examines the role of pH, ozone and irradiation in determining isotopic fractionation
Summary
1.1 The sulfur cycle in the marine boundary layerSea-salt aerosol is the dominant form of aerosol in the marine environment. Oxidation of SO2 in sea salt aerosol can reduce marine boundary layer (MBL) SO2 concentrations by up to 70 %, limiting gas phase production of H2SO4 and reducing or preventing new particle nucleation and CCN production (Chameides and Stelson, 1992; Katoshevski et al, 1999; Alexander et al, 2005). Sulfate production on sea salt aerosols shifts the sulfate size distribution towards coarse particles, leading to faster removal from the atmosphere, while having a relatively small effect on the CCN activity of the hygroscopic sea salt particles (Chameides and Stelson, 1992; Sievering et al, 1995; von Glasow, 2006). The effects of heterogeneous SO2 oxidation on the sulfur cycle in the MBL are important due to the low albedo of the ocean and the strong climatic effect of marine clouds (von Glasow and Crutzen, 2004)
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