Production of Molecular Iodine and Tri-iodide in the Frozen Solution of Iodide: Implication for Polar Atmosphere

The chemistry of reactive halogens in the polar atmosphere plays important roles in ozone and mercury depletion events, oxidizing capacity, and dimethylsulfide oxidation to form cloud-condensation nuclei. Among halogen species, the sources and emission mechanisms of inorganic iodine compounds in the...

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Bibliographic Details
Published in:Environmental Science & Technology
Main Authors: Kim, K., Yabushita, A., Okumura, M., Saiz-Lopez, A., Cuevas, Carlos A., Blaszczak-Boxe, C.S., Min, D.W., Yoon, H.I., Choi, W.
Format: Article in Journal/Newspaper
Language:unknown
Published: American Chemical Society 2016
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Online Access:http://hdl.handle.net/10261/142179
https://doi.org/10.1021/acs.est.5b05148
Description
Summary:The chemistry of reactive halogens in the polar atmosphere plays important roles in ozone and mercury depletion events, oxidizing capacity, and dimethylsulfide oxidation to form cloud-condensation nuclei. Among halogen species, the sources and emission mechanisms of inorganic iodine compounds in the polar boundary layer remain unknown. Here, we demonstrate that the production of tri-iodide (I ) via iodide oxidation, which is negligible in aqueous solution, is significantly accelerated in frozen solution, both in the presence and the absence of solar irradiation. Field experiments carried out in the Antarctic region (King George Island, 62°13′S, 58°47′W) also showed that the generation of tri-iodide via solar photo-oxidation was enhanced when iodide was added to various ice media. The emission of gaseous I from the irradiated frozen solution of iodide to the gas phase was detected by using cavity ring-down spectroscopy, which was observed both in the frozen state at 253 K and after thawing the ice at 298 K. The accelerated (photo-)oxidation of iodide and the subsequent formation of tri-iodide and I in ice appear to be related with the freeze concentration of iodide and dissolved O trapped in the ice crystal grain boundaries. We propose that an accelerated abiotic transformation of iodide to gaseous I in ice media provides a previously unrecognized formation pathway of active iodine species in the polar atmosphere. Peer Reviewed