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W2016553619 endingPage "70" @default.
W2016553619 startingPage "59" @default.
W2016553619 abstract "This work investigates the mechanism of the uranyl interaction with birnessite, one of the most common layer-type MnO2 mineral at the Earth's surface, by coupling macroscopic (surface complexation experiments) and microscopic (EXAFS measurements) approaches. The sorption of uranyl on synthetic hexagonal birnessite, the low-pH birnessite form, was studied under various conditions of pH (3–6), electrolyte backgrounds (0.1 M NaClO4, NaNO3 and Na2CO3), and solid/liquid ratios (from 0.27 to 4.5 g/L). Sorption isotherms exhibit a complex form indicative of at least two types of sorption sites. EXAFS data reveal the presence of two equatorial O shells at ca. 2.32 Å and 2.46 Å for all the samples, and a Mn shell at ca. 3.38 Å in the low-pH (≤ 5) samples only. No U–U pair was detected, despite the presence of polynuclear dissolved species in some of the samples. From the combination of the sorption isotherms and EXAFS results, a structural model for the sorption of uranyl onto hexagonal birnessite is proposed, in which two energetically different sites are involved. At low pH (≤ 5) a bidentate edge-sharing complex with Mn octahedra of the mineral edges can be inferred, whereas bidentate corner-sharing and/or monodentate complexation to layer vacancies would most likely describe EXAFS features of higher pH samples. A diffuse double layer model of surface complexation was developed for describing within the same framework the uranyl sorption against pH, involving both high-affinity (Mn octahedra edge) and low-affinity (above layer vacancies) sites. The comparison of the uranyl sorption onto hexagonal birnessite and various related environmental minerals shows that the affinity of uranyl for birnessite largely exceeds the sorption observed on montmorillonite and zeolite and turns out to be comparable to iron oxides, confirming the potential role of phyllomanganates to the control of uranyl mobility in post-oxic acidic environments." @default.
W2016553619 created "2016-06-24" @default.
W2016553619 creator A5001250260 @default.
W2016553619 creator A5003223363 @default.
W2016553619 creator A5046461735 @default.
W2016553619 creator A5056808744 @default.
W2016553619 date "2014-05-01" @default.
W2016553619 modified "2023-09-30" @default.
W2016553619 title "Uranyl sorption onto birnessite: A surface complexation modeling and EXAFS study" @default.
W2016553619 cites W124511460 @default.
W2016553619 cites W1956087068 @default.
W2016553619 cites W1967412223 @default.
W2016553619 cites W1967885010 @default.
W2016553619 cites W1971297964 @default.
W2016553619 cites W1977871054 @default.
W2016553619 cites W1980361407 @default.
W2016553619 cites W1986362604 @default.
W2016553619 cites W1988960405 @default.
W2016553619 cites W1992081213 @default.
W2016553619 cites W1995706097 @default.
W2016553619 cites W1996768414 @default.
W2016553619 cites W1998595642 @default.
W2016553619 cites W1999874674 @default.
W2016553619 cites W2000064602 @default.
W2016553619 cites W2002060434 @default.
W2016553619 cites W2002877849 @default.
W2016553619 cites W2007333648 @default.
W2016553619 cites W2009146224 @default.
W2016553619 cites W2009647096 @default.
W2016553619 cites W2012252833 @default.
W2016553619 cites W2013476628 @default.
W2016553619 cites W2016998298 @default.
W2016553619 cites W2020218467 @default.
W2016553619 cites W2020515714 @default.
W2016553619 cites W2021165726 @default.
W2016553619 cites W2027293224 @default.
W2016553619 cites W2027519825 @default.
W2016553619 cites W2027853603 @default.
W2016553619 cites W2029893269 @default.
W2016553619 cites W2030314448 @default.
W2016553619 cites W2030607542 @default.
W2016553619 cites W2032678288 @default.
W2016553619 cites W2033792845 @default.
W2016553619 cites W2034304055 @default.
W2016553619 cites W2036160778 @default.
W2016553619 cites W2037689872 @default.
W2016553619 cites W2038869979 @default.
W2016553619 cites W2050775407 @default.
W2016553619 cites W2052321137 @default.
W2016553619 cites W2057104903 @default.
W2016553619 cites W2059201219 @default.
W2016553619 cites W2060217799 @default.
W2016553619 cites W2063994607 @default.
W2016553619 cites W2068073342 @default.
W2016553619 cites W2069326228 @default.
W2016553619 cites W2070227796 @default.
W2016553619 cites W2072064998 @default.
W2016553619 cites W2072236500 @default.
W2016553619 cites W2075007064 @default.
W2016553619 cites W2075295962 @default.
W2016553619 cites W2086291392 @default.
W2016553619 cites W2086694157 @default.
W2016553619 cites W2091225476 @default.
W2016553619 cites W2093685176 @default.
W2016553619 cites W2094502864 @default.
W2016553619 cites W2094545984 @default.
W2016553619 cites W2095664287 @default.
W2016553619 cites W2098107208 @default.
W2016553619 cites W2110221529 @default.
W2016553619 cites W2111289042 @default.
W2016553619 cites W2119574279 @default.
W2016553619 cites W2125248059 @default.
W2016553619 cites W2126695945 @default.
W2016553619 cites W2130441958 @default.
W2016553619 cites W2134260166 @default.
W2016553619 cites W2140408128 @default.
W2016553619 cites W2149421142 @default.
W2016553619 cites W2149626823 @default.
W2016553619 cites W2152928589 @default.
W2016553619 cites W2153982032 @default.
W2016553619 cites W2164701866 @default.
W2016553619 cites W2170424371 @default.
W2016553619 cites W2289960406 @default.
W2016553619 cites W2303609792 @default.
W2016553619 cites W2306153471 @default.
W2016553619 cites W2404898580 @default.
W2016553619 cites W2418180711 @default.
W2016553619 cites W2465292115 @default.
W2016553619 cites W4241387305 @default.
W2016553619 doi "https://doi.org/10.1016/j.chemgeo.2014.02.025" @default.
W2016553619 hasPublicationYear "2014" @default.
W2016553619 type Work @default.
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