Sulfur dioxide reactions on ice surfaces: implications for dry deposition to snow

Martha H. Conklin , Richard A. Sommerfeld , S.Kay Laird , John E. Villinski
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引用次数: 39

Abstract

Controlled exposure of ice to a reactive gas, SO2, demonstrated the importance of the chemical composition of the ice surface on the accumulation of acidity in snow. In a series of bench-scale continuous-flow column experiments run at four temperatures (−1, −8, −30 and −60°C), SO2 was shown to dissolve and to react with other species in the ice-air interfacial region at temperatures approaching the melting point of ice. Experiments consisted of passing air containing SO2 through glass columns packed with 100-μm ice spheres of varying bulk composition (0–5 μM H2O2, and 0–1 mM NaCl), and analysing SO2 in the air and SO42− in the ice. At all temperatures (−60 to −1°C), increased retention volumes were found for increasing ionic strength and oxidant concentration. At the coldest temperatures and with no NaCl, increased retention volumes for −60 vs −30°C are consistent with SO2 uptake by physical adsorption. At warmer temperatures, −8 and −1°C, the observed tailing in the sorption curves indicated that other processes besides physical adsorption were occurring. The desorption curves showed a rapid decrease for the warmer temperatures, indicating the sorbed SO2 is irreversibly oxidized to SO42−. Results indicate that aqueous-phase reactions can occur below −8°C (i.e. −30 and −60°C). Results for different salt concentrations show that increasing ionic strength facilitates SO2 oxidation at colder temperatures, which is consistent with freezing point depression. One environmental implication is that snowpacks in areas with background SO2, can accumulate acidity during the winter months. As acidity accumulates, the solubility of SO2 will decrease causing a concomitant decrease in the air-to-surface flux of SO2. Modeling dry deposition of gases to snow surfaces should incorporate the changing composition of the ice surface.

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二氧化硫在冰面上的反应:对雪干沉积的影响
将冰受控地暴露于活性气体SO2中,证明了冰表面的化学成分对雪中酸性积累的重要性。在四种温度(- 1、- 8、- 30和- 60℃)下进行的一系列实验中,SO2在接近冰熔点的温度下溶解并与冰-空气界面区域的其他物质发生反应。实验包括将含有SO2的空气通过填充有不同体积成分(0-5 μM H2O2和0-1 mM NaCl)的100 μM冰球的玻璃柱,分析空气中的SO2和冰中的SO42−。在所有温度下(- 60至- 1°C),离子强度和氧化剂浓度增加,保留体积增加。在最冷的温度和没有NaCl的情况下,−60 vs−30°C的保留体积增加与SO2的物理吸附一致。在−8℃和−1℃的温度下,吸附曲线中观察到的尾迹表明,除物理吸附外,还发生了其他过程。随着温度的升高,解吸曲线急剧下降,表明被吸附的SO2被不可逆氧化为SO42−。结果表明,在- 8°C(即- 30和- 60°C)以下可以发生水相反应。不同盐浓度下的结果表明,离子强度的增加有利于SO2在较低温度下的氧化,这与冰点降低一致。对环境的影响之一是,在背景二氧化硫含量较高的地区,积雪会在冬季积累酸度。随着酸度的积累,SO2的溶解度会降低,导致SO2的空气-表面通量随之降低。模拟气体在雪表面的干沉积过程应该考虑到冰表面成分的变化。
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