Your search keyword '"Yi-Fang Ho"' showing total 13 results

1. Role of natural organic matter on iodine and 239,240Pu distribution and mobility in environmental samples from the northwestern Fukushima Prefecture, Japan

Author

Nobuhide Fujitake, Peter H. Santschi, Saijin Zhang, Nobuhito Ohte, Daniel I. Kaplan, Kathleen A. Schwehr, Chen Xu, Yuko Sugiyama, Chris M. Yeager, and Yi-Fang Ho

Subjects

Biogeochemical cycle, Stemflow, 010504 meteorology & atmospheric sciences, Soil test, Health, Toxicology and Mutagenesis, Forests, 010501 environmental sciences, 01 natural sciences, Iodine Radioisotopes, Japan, Radiation Monitoring, Fukushima Nuclear Accident, Soil Pollutants, Radioactive, Environmental Chemistry, Waste Management and Disposal, Humic Substances, 0105 earth and related environmental sciences, Hydrology, Total organic carbon, Chemistry, Soil organic matter, General Medicine, Throughfall, Pollution, Plutonium, Deciduous, Cesium Radioisotopes, Environmental chemistry, Soil water, Iodine

Abstract

In order to assess how environmental factors are affecting the distribution and migration of radioiodine and plutonium that were emitted from the Fukushima Dai-ichi Nuclear Power Plant (FDNPP) accident, we quantified iodine and (239,240)Pu concentration changes in soil samples with different land uses (urban, paddy, deciduous forest and coniferous forest), as well as iodine speciation in surface water and rainwater. Sampling locations were 53-63 km northwest of the FDNPP within a 75-km radius, in close proximity of each other. A ranking of the land uses by their surface soil (4 cm) stable (127)I concentrations was coniferous forestdeciduous foresturbanpaddy, and (239,240)Pu concentrations ranked as deciduous forestconiferous forestpaddy ≥ urban. Both were quite distinct from that of (134)Cs and (137)Cs: urbanconiferous forestdeciduous forestpaddy, indicating differences in their sources, deposition phases, and biogeochemical behavior in these soil systems. Although stable (127)I might not have fully equilibrated with Fukushima-derived (129)I, it likely still works as a proxy for the long-term fate of (129)I. Surficial soil (127)I content was well correlated to soil organic matter (SOM) content, regardless of land use type, suggesting that SOM might be an important factor affecting iodine biogeochemistry. Other soil chemical properties, such as Eh and pH, had strong correlations to soil (127)I content, but only within a given land use (e.g., within urban soils). Organic carbon (OC) concentrations and Eh were positively, and pH was negatively correlated to (127)I concentrations in surface water and rain samples. It is also noticeable that (127)I in the wet deposition was concentrated in both the deciduous and coniferous forest throughfall and stemfall water, respectively, comparing to the bulk rainwater. Further, both forest throughfall and stemflow water consisted exclusively of organo-iodine, suggesting all inorganic iodine in the original bulk deposition (∼ 28.6% of total iodine) have been completely converted to organo-iodine. Fukushima-derived (239,240)Pu was detectable at a distance ∼ 61 km away, NW of FDNPP. However, it is confined to the litter layer, even three years after the FDNPP accident-derived emissions. Plutonium-239,240 activities were significantly correlated with soil OC and nitrogen contents, indicating Pu may be associated with nitrogen-containing SOM, similar to what has been observed at other locations in the United States. Together, these finding suggest that natural organic matter (NOM) plays a key role in affecting the fate and transport of I and Pu and may warrant greater consideration for predicting long-term stewardship of contaminated areas and evaluating various remediation options in Japan.

Published

2016

2. Radioiodine sorption/desorption and speciation transformation by subsurface sediments from the Hanford Site

Author

Chen Xu, Hsiu-Ping Li, Peter H. Santschi, Yi-Fang Ho, Daniel I. Kaplan, Chris M. Yeager, Kathleen A. Schwehr, Russell Grandbois, Matthew Athon, Saijin Zhang, and Dawn M. Wellman

Subjects

Total organic carbon, chemistry.chemical_classification, Geologic Sediments, Hanford Site, Environmental remediation, Health, Toxicology and Mutagenesis, Radiochemistry, Iodide, Carbonates, chemistry.chemical_element, General Medicine, Iodine, Iodine Radioisotopes, Pollution, chemistry.chemical_compound, chemistry, Environmental chemistry, Environmental Chemistry, Groundwater, Waste Management and Disposal, Iodate

Abstract

During the last few decades, considerable research efforts have been extended to identify more effective remediation treatment technologies to lower the (129)I concentrations to below federal drinking water standards at the Hanford Site (Richland, USA). Few studies have taken iodate into consideration, though recently iodate, instead of iodide, was identified as the major species in the groundwater of 200-West Area within the Hanford Site. The objective of this study was thus to quantify and understand aqueous radioiodine species transformations and uptake by three sediments collected from the semi-arid, carbonate-rich environment of the Hanford subsurface. All three sediments reduced iodate (IO3(-)) to iodide (I(-)), but the loamy-sand sediment reduced more IO3(-) (100% reduced within 7 days) than the two sand-textured sediments (∼20% reduced after 28 days). No dissolved organo-iodine species were observed in any of these studies. Iodate uptake Kd values ([Isolid]/[Iaq]; 0.8-7.6 L/kg) were consistently and appreciably greater than iodide Kd values (0-5.6 L/kg). Furthermore, desorption Kd values (11.9-29.8 L/kg) for both iodate and iodide were consistently and appreciably greater than uptake Kd values (0-7.6 L/kg). Major fractions of iodine associated with the sediments were unexpectedly strongly bound, such that only 0.4-6.6 % of the total sedimentary iodine could be exchanged from the surface with KCl solution, and 0-1.2% was associated with Fe or Mn oxides (weak NH2HCl/HNO3 extractable fraction). Iodine incorporated into calcite accounted for 2.9-39.4% of the total sedimentary iodine, whereas organic carbon (OC) is likely responsible for the residual iodine (57.1-90.6%) in sediments. The OC, even at low concentrations, appeared to be controlling iodine binding to the sediments, as it was found that the greater the OC concentrations in the sediments, the greater the values of uptake Kd, desorption Kd, and the greater residual iodine concentrations (non-exchangeable, non-calcite-incorporated and non-Mn, Fe-oxide associated). This finding is of particular interest because it suggests that even very low OC concentrations

Published

2015

3. Superoxide Production by a Manganese-Oxidizing Bacterium Facilitates Iodide Oxidation

Author

Benjamin Daniel, Hsiu-Ping Li, Yi-Fang Ho, Danielle Creeley, Russell Grandbois, Chen Xu, Saijin Zhang, Peter H. Santschi, Kathy A. Schwehr, Colleen M. Hansel, Daniel I. Kaplan, and Chris M. Yeager

Subjects

Iodide, Inorganic chemistry, chemistry.chemical_element, Manganese, Iodine, Applied Microbiology and Biotechnology, Superoxide dismutase, chemistry.chemical_compound, Bacterial Proteins, Superoxides, Extracellular, Seawater, chemistry.chemical_classification, Ecology, biology, Superoxide, Iodides, Roseobacter, biology.organism_classification, Geomicrobiology, Biodegradation, Environmental, chemistry, biology.protein, Iodide oxidation, Oxidation-Reduction, Food Science, Biotechnology, Nuclear chemistry

Abstract

The release of radioactive iodine (i.e., iodine-129 and iodine-131) from nuclear reprocessing facilities is a potential threat to human health. The fate and transport of iodine are determined primarily by its redox status, but processes that affect iodine oxidation states in the environment are poorly characterized. Given the difficulty in removing electrons from iodide (I − ), naturally occurring iodide oxidation processes require strong oxidants, such as Mn oxides or microbial enzymes. In this study, we examine iodide oxidation by a marine bacterium, Roseobacter sp. AzwK-3b, which promotes Mn(II) oxidation by catalyzing the production of extracellular superoxide (O 2 − ). In the absence of Mn 2+ , Roseobacter sp. AzwK-3b cultures oxidized ∼90% of the provided iodide (10 μM) within 6 days, whereas in the presence of Mn(II), iodide oxidation occurred only after Mn(IV) formation ceased. Iodide oxidation was not observed during incubations in spent medium or with whole cells under anaerobic conditions or following heat treatment (boiling). Furthermore, iodide oxidation was significantly inhibited in the presence of superoxide dismutase and diphenylene iodonium (a general inhibitor of NADH oxidoreductases). In contrast, the addition of exogenous NADH enhanced iodide oxidation. Taken together, the results indicate that iodide oxidation was mediated primarily by extracellular superoxide generated by Roseobacter sp. AzwK-3b and not by the Mn oxides formed by this organism. Considering that extracellular superoxide formation is a widespread phenomenon among marine and terrestrial bacteria, this could represent an important pathway for iodide oxidation in some environments.

Published

2014

4. Novel molecular-level evidence of iodine binding to natural organic matter from Fourier transform ion cyclotron resonance mass spectrometry

Author

Yuko Sugiyama, Daniel I. Kaplan, Chia-Ying Chuang, Chris M. Yeager, Kimberly A. Roberts, Saijin Zhang, Hsiu-Ping Li, Peter H. Santschi, Yi-Fang Ho, Patrick G. Hatcher, Hongmei Chen, Chen Xu, and Kathleen A. Schwehr

Subjects

chemistry.chemical_classification, Environmental Engineering, Electrospray ionization, Iodide, Inorganic chemistry, chemistry.chemical_element, Iodine, Pollution, Fourier transform ion cyclotron resonance, chemistry.chemical_compound, Alicyclic compound, Electrophilic substitution, chemistry, Environmental Chemistry, Reactivity (chemistry), Waste Management and Disposal, Iodate

Abstract

Major fractions of radioiodine ((129)I) are associated with natural organic matter (NOM) in the groundwater and surface soils of the Savannah River Site (SRS). Electrospray ionization coupled to Fourier transform ion cyclotron resonance mass spectrometry (ESI-FTICR-MS) was applied to elucidate the interactions between inorganic iodine species (iodide and iodate) and a fulvic acid (FA) extracted from a SRS surface soil. Iodate is likely reduced to reactive iodine species by the lignin- and tannin-like compounds or the carboxylic-rich alicyclic molecules (CRAM), during which condensed aromatics and lignin-like compounds were generated. Iodide is catalytically oxidized into reactive iodine species by peroxides, while FA is oxidized by peroxides into more aliphatic and less aromatic compounds. Only 9% of the total identified organo-iodine compounds derived from molecules originally present in the FA, whereas most were iodine binding to newly-produced compounds. The resulting iodinated molecules were distributed in three regions in the van Krevelen diagrams, denoting unsaturated hydrocarbons, lignin and protein. Moreover, characteristics of these organo-iodine compounds, such as their relatively low O/C ratios (0.2 or0.4) and yet some degree of un-saturation close to that of lignin, have multiple important environmental implications concerning possibly less sterically-hindered aromatic ring system for iodine to get access to and a lower hydrophilicity of the molecules thus to retard their migration in the natural aquatic systems. Lastly, ~69% of the identified organo-iodine species contains nitrogen, which is presumably present as NH2 or HNCOR groups and a ring-activating functionality to favor the electrophilic substitution. The ESI-FTICR-MS technique provides novel evidence to better understand the reactivity and scavenging properties of NOM towards radioiodine and possible influence of NOM on (129)I migration.

Published

2013

5. Molecular environment of stable iodine and radioiodine (129I) in natural organic matter: Evidence inferred from NMR and binding experiments at environmentally relevant concentrations

Author

Patrick G. Hatcher, Peter H. Santschi, Robin Brinkmeyer, Kathleen A. Schwehr, Kimberly A. Roberts, Junyan Zhong, Saijin Zhang, Chris M. Yeager, Hsiu-Ping Li, Chen Xu, Daniel I. Kaplan, and Yi-Fang Ho

Subjects

chemistry.chemical_classification, Soil organic matter, chemistry.chemical_element, Iodine, complex mixtures, Colloid, chemistry.chemical_compound, chemistry, Geochemistry and Petrology, Environmental chemistry, Amide, Soil water, Proton NMR, Humic acid, Organic matter

Abstract

129 I is a major by-product of nuclear fission and had become one of the major radiation risk drivers at Department of Energy (DOE) sites. 129 I is present at elevated levels in the surface soils of the Savannah River Site (SRS) F-Area and was found to be bound predominantly to soil organic matter (SOM). Naturally bound 127 I and 129 I to sequentially extracted humic acids (HAs), fulvic acids (FAs) and a water extractable colloid (WEC) were measured in a 129 I-contaminated wetland surface soil located on the SRS. WEC is a predominantly colloidal organic fraction obtained from soil re-suspension experiments to mimic the fraction that may be released during groundwater exfiltration, storm water or surface runoff events. For the first time, NMR techniques were applied to infer the molecular environment of naturally occurring stable iodine and radioiodine binding to SOM. Iodine uptake partitioning coefficients ( K d ) by these SOM samples at ambient iodine concentrations were also measured and related to quantitative structural analyses by 13 C DPMAS NMR and solution state 1 H NMR on the eight humic acid fractions. By assessing the molecular environment of iodine, it was found that it was closely associated with the aromatic regions containing esterified products of phenolic and formic acids or other aliphatic carboxylic acids, amide functionalities, quinone-like structures activated by electron-donating groups (e.g., NH 2 ), or a hemicellulose–lignin-like complex with phenyl-glycosidic linkages. However, FAs and WEC contained much greater concentrations of 127 I or 129 I than HAs. The contrasting radioiodine contents among the three different types of SOM (HAs, FAs and WEC) suggest that the iodine binding environment cannot be explained solely by the difference in the amount of their reactive binding sites. Instead, indirect evidence indicates that the macro-molecular conformation, such as the hydrophobic aliphatic periphery hindering the active aromatic cores and the hydrophilic polysaccharides favoring the access by hydrophilic iodine species, also influences iodine–SOM interactions.

Published

2012

6. Is soil natural organic matter a sink or source for mobile radioiodine (129I) at the Savannah River Site?

Author

Peter H. Santschi, Chen Xu, Robin Brinkmeyer, Kathleen A. Schwehr, Shigeyoshi Otosaka, Kimberly A. Roberts, Saijin Zhang, Daniel I. Kaplan, Hsiu-Ping Li, Chris M. Yeager, Eric J. Miller, and Yi-Fang Ho

Subjects

chemistry.chemical_classification, chemistry, Geochemistry and Petrology, Environmental remediation, Savannah River Site, Environmental chemistry, Soil organic matter, Soil water, chemistry.chemical_element, Organic matter, Iodine, Groundwater, Humus

Abstract

129 I is one of the three major radiation risk contributors to the public as a consequence of past nuclear processing activities at Department of Energy (DOE) facilities. Elevated levels of 129 I are present in the surface soils of F-Area of Savannah River Site, which used to be an isotope separation facility for the production of nuclear weapons components. The 129 I in soils is thought to be bound predominantly to soil organic matter (SOM). Measurements of stable 127 I and radioactive 129 I in humic acids (HAs) and fulvic acids (FAs) obtained by five successive alkaline, two glycerol and one citric acid–alkaline extraction, demonstrated that these extractable humic substances (HS) together account for 54–56% and 46% of the total 127 I and 129 I in the soil, respectively. The remainder was likely bound to residual SOM. The iodine content (μg-I/g-C) generally decreased with each subsequent extract, while 129 I/ 127 I increased concurrently. The coincident variations in chemical compositions, aromaticity (estimated by UV spectroscopy), functional groups (e.g., aliphatic), degree of humification, relative migration in the hydrophobic interaction column, and molecular weight indicated that: (1) iodine in different HAs was bound to a small-size aromatic subunit (∼10 kDa); (2) the large-size subunit (∼90 kDa), which likely linked the small-size unit through some weak chemical forces (hydrogen bonds, hydrophobic or electrostatic interactions), determined the relative mobility of iodine bound to organic matter; (3) from the strong correlation between iodine content and aromaticity in the HAs, we suggested that iodine incorporation into the SOM via covalent aromatic C–I bond is the key mechanism controlling iodine behavior in this system. However, this relationship is not universal for all fractions of organic matter as evidenced from the different slopes of this relationship at the two sampling sites, as well as from the different relationships for HAs and FAs, respectively. These differences in iodination are due to different SOM molecular sizes, compositions, and availability of preferred iodination sites. 129 I in the soil downstream from the contaminated site and near a wetland abruptly dropped below our detection limit (0.5 pCi- 129 I/g-soil), which suggests that the high SOM in the plume soil around the 129 I-contaminated F-Area might be a natural barrier to scavenge radioiodine released from the nuclear waste repository by forming organo-iodine compounds. Soil resuspension experiments showed that mobile 129 I was mostly associated with a low average molecular weight amphiphilic organic carrier (13.5–15 kDa). SOM clearly behaves as a sink for iodine at the Savannah River Site F-Area. However, this work demonstrates that a small fraction of the SOM can also behave as a source, namely that a small fraction that may be readily dispersible under some environmental conditions and presumably release iodine in the organic-colloidal form. This radioiodinated organo-colloid likely can get into the groundwater through infiltration or surface runoff where it might migrate further into the wetlands. Results from this study provide the geochemical basis for future 129 I migration controls, remediation, and/or land–groundwater management strategies.

Published

2011

7. Factors controlling mobility of 127I and 129I species in an acidic groundwater plume at the Savannah River Site

Author

Robin Brinkmeyer, Chen Xu, Peter H. Santschi, Shigeyoshi Otosaka, Yi-Fang Ho, Kathleen A. Schwehr, Chris M. Yeager, Kimberly A. Roberts, Saijin Zhang, Daniel I. Kaplan, and Hsiu-Ping Li

Subjects

Environmental Engineering, Savannah River Site, Iodide, chemistry.chemical_element, Iodine, Iodine Radioisotopes, chemistry.chemical_compound, Rivers, Iodine Isotopes, Water Movements, Environmental Chemistry, Groundwater, Waste Management and Disposal, Iodate, Hydrology, chemistry.chemical_classification, Total organic carbon, Hydrogen-Ion Concentration, Pollution, United States, United States Government Agencies, Plume, chemistry, Environmental chemistry, Oxidation-Reduction, Environmental Monitoring

Abstract

In order to quantify changes in iodine speciation and to assess factors controlling the distribution and mobility of iodine at an iodine-129 ((129)I) contaminated site located at the U.S. Department of Energy's Savannah River Site (SRS), spatial distributions and transformation of (129)I and stable iodine ((127)I) species in groundwater were investigated along a gradient in redox potential (654 to 360 mV), organic carbon concentration (5 to 60 μmol L(-1)), and pH (pH 3.2 to 6.8). Total (129)I concentration in groundwater was 8.6±2.8 Bq L(-1) immediately downstream of a former waste seepage basin (well FSB-95DR), and decreased with distance from the seepage basin. (127)I concentration decreased similarly to that of (129)I. Elevated concentrations of (127)I or (129)I were not detected in groundwater collected from wells located outside of the mixed waste plume of this area. At FSB-95DR, the majority (55-86%) of iodine existed as iodide for both (127)I and (129)I. Then, as the iodide move down gradient, some of it transformed into iodate and organo-iodine. Considering that iodate has a higher K(d) value than iodide, we hypothesize that the production of iodate in groundwater resulted in the removal of iodine from the groundwater and consequently decreased concentrations of (127)I and (129)I in downstream areas. Significant amounts of organo-iodine species (30-82% of the total iodine) were also observed at upstream wells, including those outside the mixed waste plume. Concentrations of groundwater iodide decreased at a faster rate than organo-iodine along the transect from the seepage basin. We concluded that removal of iodine from the groundwater through the formation of high molecular weight organo-iodine species is complicated by the release of other more mobile organo-iodine species in the groundwater.

Published

2011

8. Temporal variation of iodine concentration and speciation (127I and 129I) in wetland groundwater from the Savannah River Site, USA

Author

Danielle Creeley, Kimberly A. Roberts, Peter H. Santschi, Saijin Zhang, Chen Xu, Kathleen A. Schwehr, Yi-Fang Ho, Hsiu-Ping Li, Chris M. Yeager, and Daniel I. Kaplan

Subjects

Biogeochemical cycle, Water Pollutants, Radioactive, Savannah River Site, media_common.quotation_subject, South Carolina, Aquifer, Wetland, Iodine Radioisotopes, chemistry.chemical_compound, Nitrate, Rivers, Risk Factors, Iodine Isotopes, Environmental Chemistry, Groundwater, media_common, Hydrology, geography, geography.geographical_feature_category, General Chemistry, Models, Theoretical, Plume, Speciation, chemistry, Wetlands, Environmental science, Iodine

Abstract

(129)I derived from a former radionuclide disposal basin located on the Savannah River Site (SRS) has concentrated in a wetland 600 m downstream. To evaluate temporal environmental influences on iodine speciation and mobility in this subtropical wetland environment, groundwater was collected over a three-year period (2010-2012) from a single location. Total (127)I and (129)I showed significant temporal variations, ranging from 68-196 nM for (127)I and5-133 pCi/L for (129)I. These iodine isotopes were significantly correlated with groundwater acidity and nitrate, two parameters elevated within the contaminant plume. Additionally, (129)I levels were significantly correlated with those of (127)I, suggesting that biogeochemical controls on (127)I and (129)I are similar within the SRS aquifer/wetland system. Iodine speciation demonstrates temporal variations as well, reflecting effects from surface recharges followed by acidification of groundwater and subsequent formation of anaerobic conditions. Our results reveal a complex system where few single ancillary parameters changed in a systematic manner with iodine speciation. Instead, changes in groundwater chemistry and microbial activity, driven by surface hydrological events, interact to control iodine speciation and mobility. Future radiological risk models should consider the flux of (129)I in response to temporal changes in wetland hydrologic and chemical conditions.

Published

2014

9. Concentration-dependent mobility, retardation, and speciation of iodine in surface sediment from the Savannah River Site

Author

Chen Xu, Jinzhou Du, Chris M. Yeager, Yi-Fang Ho, Peter H. Santschi, Robin Brinkmeyer, Kimberly A. Roberts, Hsiu-Ping Li, Saijin Zhang, Daniel I. Kaplan, Kathleen A. Schwehr, and Hyun-Shik Chang

Subjects

Geologic Sediments, Georgia, Iodide, Mineralogy, chemistry.chemical_element, Iodine, Iodine Radioisotopes, chemistry.chemical_compound, Adsorption, Rivers, Water Movements, Environmental Chemistry, Iodate, Total organic carbon, chemistry.chemical_classification, Binding Sites, Sorption, Biological Transport, General Chemistry, Carbon, chemistry, Environmental chemistry, Soil water

Abstract

Iodine occurs in multiple oxidation states in aquatic systems in the form of organic and inorganic species. This feature leads to complex biogeochemical cycling of stable iodine and its long-lived isotope, (129)I. In this study, we investigated the sorption, transport, and interconversion of iodine species by comparing their mobility in groundwaters at ambient concentrations of iodine species (10(-8) to 10(-7) M) to those at artificially elevated concentrations (78.7 μM), which often are used in laboratory analyses. Results demonstrate that the mobility of iodine species greatly depends on, in addition to the type of species, the iodine concentration used, presumably limited by the number of surface organic carbon binding sites to form covalent bonds. At ambient concentrations, iodide and iodate were significantly retarded (K(d) values as high as 49 mL g(-1)), whereas at concentrations of 78.7 μM, iodide traveled along with the water without retardation. Appreciable amounts of iodide during transport were retained in soils due to iodination of organic carbon, specifically retained by aromatic carbon. At high input concentration of iodate (78.7 μM), iodate was found to be reduced to iodide and subsequently followed the transport behavior of iodide. These experiments underscore the importance of studying iodine geochemistry at ambient concentrations and demonstrate the dynamic nature of their speciation during transport conditions.

Published

2011

10. Response to Comment on 'Iodine-129 and Iodine-127 Speciation in Groundwater at Hanford Site, U.S.: Iodate Incorporation into Calcite'

Author

Chen Xu, Kathleen A. Schwehr, Russell Grandbois, Danielle Creeley, Peter H. Santschi, Saijin Zhang, Dawn M. Wellman, Yi-Fang Ho, Hsiu-Ping Li, Chris M. Yeager, and Daniel I. Kaplan

Subjects

Calcite, Water Pollutants, Radioactive, Hanford Site, media_common.quotation_subject, Iodates, Mineralogy, chemistry.chemical_element, Sediment, General Chemistry, Iodine, Calcium Carbonate, Speciation, chemistry.chemical_compound, chemistry, Soil water, Environmental Chemistry, Groundwater, Iodate, Geology, media_common

Abstract

In his comment on our paper “Iodine-129 and Iodine-127 Speciation in Groundwater at Hanford Site, U.S.: Iodate Incorporation into Calcite”, Lu specified three concerns for Zhang et al’s study,1 including (1) precipitation mechanism (degassing vs freezing), (2) analytical methods, and (3) mass balance control. In response, comparative and comprehensive discussions on the precipitation mechanisms and iodine incorporation can be found in the paper, as well as below. This includes additional experiments of iodine distribution and speciation in calcite precipitates. In addition, the measurements of total iodine in soils/sediment were clarified below as well. The calculations on mass balance in this comment were clarified by using correct data sets. Lu proposed that freezing samples

Published

2013

11. Temporal Variation of Iodine Concentration and Speciation (127I and 129I) in Wetland Groundwater from the Savannah River Site, USA.

Author

Saijin Zhang, Yi-Fang Ho, Creeley, Danielle, Roberts, Kimberly A., Chen Xu, Hsiu-Ping Li, Schwehr, Kathleen A., Kaplan, Daniel I., Yeager, Chris M., and Santschi, Peter H.

Subjects

*GROUNDWATER research, *IODINE, *CHEMICAL speciation, *RADIOISOTOPES, *HYDROLOGY, SAVANNAH River Site (S.C.)

Abstract

129I derived from a former radionuclide disposal basin located on the Savannah River Site (SRS) has concentrated in a wetland 600 m downstream. To evaluate temporal environmental influences on iodine speciation and mobility in this subtropical wetland environment, groundwater was collected over a three-year period (2010-2012) from a single location. Total 127I and 129I showed significant temporal variations, ranging from 68-196 nM for 127I and <5-133 pCi/L for 129I. These iodine isotopes were significantly correlated with groundwater acidity and nitrate, two parameters elevated within the contaminant plume. Additionally, l21 levels were significantly correlated with those of 127I, suggesting that biogeochemical controls on 127I and 129I are similar within the SRS aquifer/ wetland system. Iodine speciation demonstrates temporal variations as well, reflecting effects from surface recharges followed by acidification of groundwater and subsequent formation of anaerobic conditions. Our results reveal a complex system where few single ancillary parameters changed in a systematic manner with iodine speciation. Instead, changes in groundwater chemistry and microbial activity, driven by surface hydrologrcal events, interact to control iodine speciation and mobility. Future radiological risk models should consider the flux of 129I in response to temporal changes in wetland hydrologic and chemical conditions. [ABSTRACT FROM AUTHOR]

Published

2014

12. Novel molecular-level evidence of iodine binding to natural organic matter from Fourier transform ion cyclotron resonance mass spectrometry.

Author

Chen Xu, Hongmei Chen, Yuko Sugiyama, Saijin Zhang, Hsiu-Ping Li, Yi-Fang Ho, Chia-ying Chuang, Schwehr, Kathleen A., Kaplan, Daniel I., Yeager, Chris, Roberts, Kimberly A., Hatcher, Patrick G., and Santschi, Peter H.

Subjects

*IODINE, *ORGANIC compounds & the environment, *CYCLOTRON resonance, *DISSOLVED organic matter, *FOURIER transform infrared spectroscopy, *EXTRACTION (Chemistry), *ENVIRONMENTAL chemistry, *SOIL temperature

Abstract

Major fractions of radioiodine (129I) are associated with natural organic matter (NOM) in the groundwater and surface soils of the Savannah River Site (SRS). Electrospray ionization coupled to Fourier transform ion cyclotron resonance mass spectrometry (ESI-FTICR-MS) was applied to elucidate the interactions between inorganic iodine species (iodide and iodate) and a fulvic acid (FA) extracted from a SRS surface soil. Iodate is likely reduced to reactive iodine species by the lignin- and tannin-like compounds or the carboxylic-rich alicyclic molecules (CRAM), during which condensed aromatics and lignin-like compounds were generated. Iodide is catalytically oxidized into reactive iodine species by peroxides, while FA is oxidized by peroxides into more aliphatic and less aromatic compounds. Only 9% of the total identified organo-iodine compounds derived from molecules originally present in the FA, whereas most were iodine binding to newly-produced compounds. The resulting iodinated molecules were distributed in three regions in the van Krevelen diagrams, denoting unsaturated hydrocarbons, lignin and protein. Moreover, characteristics of these organo-iodine compounds, such as their relatively low O/C ratios (<0.2 or <0.4) and yet some degree of un-saturation close to that of lignin, have multiple important environmental implications concerning possibly less sterically-hindered aromatic ring system for iodine to get access to and a lower hydrophilicity of the molecules thus to retard their migration in the natural aquatic systems. Lastly, ~69% of the identified organo-iodine species contains nitrogen, which is presumably present as 一NH2 or 一HNCOR groups and a ring-activating functionality to favor the electrophilic substitution. The ESI-FTICR-MS technique provides novel evidence to better understand the reactivity and scavenging properties of NOM towards radioiodine and possible influence of NOM on 129I migration. [ABSTRACT FROM AUTHOR]

Published

2013

13. Response to Comment on "Iodine-129 and lodine-127 Speciation in Groundwater at Hanford Site, U.S.: lodate Incorporation into Calcite".

Author

Saijin Zhang, Chen XU, Creeley, Danielle, Yi-Fang Ho, Hsiu-Ping Li, Grandbois, Russell, Schwehr, Kathleen A., Kaplan, Daniel I., Yeager, Chris M., Wellman, Dawn, and Santschi, Peter H.

Subjects

*GROUNDWATER, *IODINE, *CALCITE

Abstract

A response to a letter to the editor commenting on the article "Iodine-1209 and Iodine-127 Speciation in Groundwater at the Hanford Site, U.S.: Iodate Incorporation Into Calcite," published in the previous issue, is presented.

Published

2013