A Negative Feedback Between Anthropogenic Ozone Pollution and Enhanced Ocean Emissions of Iodine

Wednesday, 17 December 2014
Alfonso Saiz-Lopez1, Cristina Prados-Roman1, Carlos Cuevas1, Rafael Fernandez1, J F Lamarque2 and Douglas Edward Kinnison2, (1)Institute of Physical Chemistry Rocasolano, CSIC, Madrid, Spain, (2)National Center for Atmospheric Research, Boulder, CO, United States
Naturally emitted from the oceans, iodine compounds efficiently destroy atmospheric ozone and reduce its positive radiative forcing effects in the troposphere. Emissions of inorganic iodine have been experimentally shown to depend on the deposition to the oceans of tropospheric ozone, whose concentrations have significantly increased since 1850 as a result of human activities. A chemistry-climate model is used to quantify the current ocean emissions of inorganic iodine and assess the impact that the anthropogenic increase of tropospheric ozone has had on the natural cycle of iodine in the marine environment since pre-industrial times. Results included in this communication indicate that the human-driven enhancement of tropospheric ozone has doubled the oceanic inorganic iodine emissions following the reaction of ozone with iodide at the sea surface. The consequent build-up of atmospheric iodine, with maximum enhancements of up to 70% with respect to preindustrial times in continental pollution outflow regions, has in turn accelerated the ozone chemical loss over the oceans with strong spatial patterns. We suggest that this ocean-atmosphere interaction represents a negative geochemical feedback loop by which current ocean emissions of iodine act as a natural buffer for ozone pollution and its radiative forcing in the global marine environment.