Microbial Contribution to Global Iodine Cycling: Volatilization, Accumulation, Reduction, Oxidation, and Sorption of Iodine

Amachi, Seigo

doi:10.1264/jsme2.me08548

Cited by 144 publications

(114 citation statements)

References 91 publications

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“…Instead, we attribute the increase in subsurface 137 Cs inventory to its translocation from a deeper reservoir (27) during the seasonal transition from winter dormancy to spring growth. Iodine is a micronutrient in its own right, widely implicated in soil microbial metabolism (29,30). While the enrichment pattern or process may not be identical for iodine as for cesium, as the former is derived from a new, atmospheric source and the latter from an old, subsurface source, we propose that the active enrichment of iodine in surface soils or root mat is not unexpected (31).…”

Section: Resultsmentioning

confidence: 82%

Surficial redistribution of fallout¹³¹iodine in a small temperate catchment

Landis

Hamm²,

Renshaw³

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

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Isotopes of iodine play significant environmental roles, including a limiting micronutrient ( 127 I), an acute radiotoxin ( 131 I), and a geochemical tracer ( 129 I). But the cycling of iodine through terrestrial ecosystems is poorly understood, due to its complex environmental chemistry and low natural abundance. To better understand iodine transport and fate in a terrestrial ecosystem, we traced fallout 131 iodine throughout a small temperate catchment following contamination by the 11 March 2011 failure of the Fukushima Daiichi nuclear power facility. We find that radioiodine fallout is actively and efficiently scavenged by the soil system, where it is continuously focused to surface soils over a period of weeks following deposition. Mobilization of historic (pre-Fukushima) 137 cesium observed concurrently in these soils suggests that the focusing of iodine to surface soils may be biologically mediated. Atmospherically deposited iodine is subsequently redistributed from the soil system via fluvial processes in a manner analogous to that of the particle-reactive tracer 7 beryllium, a consequence of the radionuclides’ shared sorption affinity for fine, particulate organic matter. These processes of surficial redistribution create iodine hotspots in the terrestrial environment where fine, particulate organic matter accumulates, and in this manner regulate the delivery of iodine nutrients and toxins alike from small catchments to larger river systems, lakes and estuaries.

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Section: Resultsmentioning

confidence: 82%

Surficial redistribution of fallout¹³¹iodine in a small temperate catchment

Landis

Hamm²,

Renshaw³

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

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“…CH 3 I and CH 2 I 2 has been observed in the field and the laboratory (Manley and Dastoor, 1988;Amachi et al, 2001;Fuse et al, 2003;Amachi, 2008). Large uncertainties regarding the production of halocarbons in the ocean remain.…”

Section: H Hepach Et Al: Halocarbons In the Atlantic Cold Tonguementioning

confidence: 97%

Halocarbon emissions and sources in the equatorial Atlantic Cold Tongue

et al. 2015

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Abstract.Halocarbons from oceanic sources contribute to halogens in the troposphere, and can be transported into the stratosphere where they take part in ozone depletion. This paper presents distribution and sources in the equatorial Atlantic from June and July 2011 of the four compounds bromoform (CHBr 3 ), dibromomethane (CH 2 Br 2 ), methyl iodide (CH 3 I) and diiodomethane (CH 2 I 2 ). Enhanced biological production during the Atlantic Cold Tongue (ACT) season, indicated by phytoplankton pigment concentrations, led to elevated concentrations of CHBr 3 of up to 44.7 and up to 9.2 pmol L −1 for CH 2 Br 2 in surface water, which is comparable to other tropical upwelling systems. While both compounds correlated very well with each other in the surface water, CH 2 Br 2 was often more elevated in greater depth than CHBr 3 , which showed maxima in the vicinity of the deep chlorophyll maximum. The deeper maximum of CH 2 Br 2 indicates an additional source in comparison to CHBr 3 or a slower degradation of CH 2 Br 2 . Concentrations of CH 3 I of up to 12.8 pmol L −1 in the surface water were measured. In contrary to expectations of a predominantly photochemical source in the tropical ocean, its distribution was mostly in agreement with biological parameters, indicating a biological source. CH 2 I 2 was very low in the near surface water with maximum concentrations of only 3.7 pmol L −1 . CH 2 I 2 showed distinct maxima in deeper waters similar to CH 2 Br 2 . For the first time, diapycnal fluxes of the four halocarbons from the upper thermocline into and out of the mixed layer were determined. These fluxes were low in comparison to the halocarbon sea-to-air fluxes. This indicates that despite the observed maximum concentrations at depth, production in the surface mixed layer is the main oceanic source for all four compounds and one of the main driving factors of their emissions into the atmosphere in the ACTregion. The calculated production rates of the compounds in the mixed layer are 34 ± 65 pmol m −3 h −1 for CHBr 3 , 10 ± 12 pmol m −3 h −1 for CH 2 Br 2 , 21 ± 24 pmol m −3 h −1 for CH 3 I and 384 ± 318 pmol m −3 h −1 for CH 2 I 2 determined from 13 depth profiles.

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“…Oceans are considered the primary source of iodine; accordingly, our understanding of biological transformations of iodine is derived largely from those processes that have been studied in marine environments. Based on thermodynamic considerations iodate/iodide levels in seawater are in disequilibrium, with iodide found at levels much higher than would be expected, especially in certain surface waters, coastal and estuary regions, deep oxygenated water, and porewater of marine sediments where I -concentration up to 40 µg L -1 have been measured (Amachi, 2008;Farrenkopf et al, 1997). The conversion of IO 3 -to I -is thought to be catalyzed primarily via microbial activity, perhaps by the enzyme nitrate reductase or release of I -from C-I or N-I bonds upon decomposition of organic matter (Farrenkopf et Organic iodine species, including CH 3 I, CH 2 ClI, CH 2 I 2 and CH 3 CH 2 I, are found at relatively low concentrations (< 5% of total I) in the open ocean, but concentrations between 5-40% of total dissolved iodine are not uncommon in coastal and estuary systems (Schwehr and Santschi, 2003;Wong and Cheng, 1998;Hou et al, 2009b).…”

Section: Biological Reactions and The Global Iodine Cyclementioning

confidence: 99%

“…Microorganisms can catalyze the reduction, oxidation, and alkylation of iodine (Amachi, 2008;Denham et al, 2009). Within the anoxic portion of the Ringold formation or within anaerobic pockets of the heterogeneous Hanford formation, the potential for iodate reduction to iodide is high since this activity has been readily detected among microorganisms involved in denitrification and iron and sulfur reduction (Amachi et al, 2007a;Councell et al, 1997;Farrenkopf et al, 1997).…”

Section: Relevance Of Microbial Processes Influencing 129 I Behavior mentioning

confidence: 99%