Uranium(6+) sorption on montmorillonite: Experimental and surface complexation modeling study

Pabalan, Roberto T.; Turner, David R.

doi:10.1007/bf00119855

Cited by 103 publications

(79 citation statements)

References 33 publications

(56 reference statements)

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“…For all kinds of bentonite, with the exception of H-bentonite, the desorption isotherms differed from the sorption isotherms, which attested to the irreversibility of the entire sorption process. Surface precipitation and surface complexation play important roles in U(VI) immobilization by bentonite [26][27][28].…”

Section: Resultsmentioning

confidence: 99%

A thermal, sorptive and spectral study of HDTMA-bentonite loaded with uranyl phosphate

Sternik

Gładysz–Płaska

Grabias

et al. 2017

J Therm Anal Calorim

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The influence of phosphate ions on the thermal stability of complexes obtained by adsorption of uranium(VI) on organobentonite was determined. Organoclay samples were prepared by the reaction of hexadecyltrimethylammonium bromide with bentonite. The isotherms of sorption/desorption of U(VI) from aqueous solutions containing phosphate ions onto different forms of bentonite were measured using the batch method. The highest amount of uranium was absorbed on HDTMAbentonite in the presence of phosphates. This may have been associated with the complexing of U(VI) ions by phosphate ions, which interacted with surfactant cations probably via electrostatic forces. A TG-DSC-MS study showed that the thermal decomposition of the surfactant sorbed on bentonite proceeded in two stages: at 200-400 and at 600-800°C. The first stage involved defragmentation and oxidation of surfactant cations present in the interior and on the surface of the mineral. The second stage involved oxidation of charcoal and simultaneous dehydroxylation of the sorbent. The oxidation of surfactant cations and the dehydroxylation of the mineral were suppressed in the presence of phosphates.

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Section: Resultsmentioning

confidence: 99%

A thermal, sorptive and spectral study of HDTMA-bentonite loaded with uranyl phosphate

Sternik

Gładysz–Płaska

Grabias

et al. 2017

J Therm Anal Calorim

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“…However, these previous studies did not consider the potential formation of uranyl-carbonate ternary surface complexes on clay surfaces because their experiments were performed either under CO 2 (g) free or low CO 2 (g) conditions. 5,29,30,32 Recently, more detailed studies by Catalano and Brown Jr. 33 and Arai et al 34 using EXAFS spectroscopy revealed that U(VI) adsorption onto montmorillonite and imogolite surfaces occurs as uranyl-carbonate ternary surface complexes in systems equilibrated with atmospheric CO 2 . Formation of polymeric surface complexes via adsorption of aqueous UO 2 ) 3 (OH) 5 + was not observed, which is consistent with our calculation that at low U(VI) concentration (≤1 μM) and in the presence of atmospheric CO 2 , the formation of aqueous UO 2 ) 3 (OH) 5 + is not favored (Figure S1 in SI).…”

Section: +mentioning

confidence: 99%

Uranium(VI) Adsorption and Surface Complexation Modeling onto Background Sediments from the F-Area Savannah River Site

Dong

Tokunaga

Davis

et al. 2012

Environ. Sci. Technol.

119

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TitleUranium(VI) adsorption and surface complexation modeling onto background sediments from the F-Area Savannah River site ABSTRACT: The mobility of an acidic uranium waste plume in the F-Area of Savannah River Site is of great concern. In order to understand and predict uranium mobility, U(VI) adsorption experiments were performed as a function of pH using background F-Area aquifer sediments and reference goethite and kaolinite (major reactive phases of F-Area sediments), and a component-additivity (CA) based surface complexation model (SCM) was developed. Our experimental results indicate that the fine fractions (≤45 μm) in sediments control U(VI) adsorption due to their large surface area, although the quartz sands show a stronger adsorption ability per unit surface area than the fine fractions at pH < 5.0. Kaolinite is a more important sorbent for U(VI) at pH < 4.0, while goethite plays a major role at pH > 4.0. Our CA model combines an existing U(VI) SCM for goethite and a modified U(VI) SCM for kaolinite along with estimated relative surface area abundances of these component minerals. The modeling approach successfully predicts U(VI) adsorption behavior by the background F-Area sediments. The model suggests that exchange sites on kaolinite dominate U(VI) adsorption at pH < 4.0, goethite and kaolinite edge sites cocontribute to U(VI) adsorption at pH 4.0−6.0, and goethite dominates U(VI) adsorption at pH > 6.0.

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“…At pH and carbonate concentrations typical of natural waters, sorption of U(6+) on montmorillonite can vary by four orders of magnitude and can become negligible at high pH. A Diffuse-Layer model (DLM) assuming aluminol (>AlOH ∘ ) and silanol (>SiOH ∘ ) edge sites and two U(6+) surface complexation reactions per site effectively simulates the complex sorption behavior observed in the U(6+)-H 2 O-CO 2 -montmorillonite system at an ionic strength of 0.1 M and pH > 3 5 [7].…”

Section: Introductionmentioning

confidence: 99%

Sorption of Uranium(VI) and Thorium(IV) by Jordanian Bentonite

Khalili

Salameh

Shaybe

2012

Journal of Chemistry

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Puri�cation of raw bentonite was done to remove quartz. is includes mixing the raw bentonite with water and then centrifuge it at �50 rpm; this process is repeated until white puri�ed bentonite is obtained. �RD, �RF, FTIR, and SEM techniques will be used for the characterization of puri�ed bentonite. e sorption behavior of puri�ed Jordanian bentonite towards UO 2 2+and  4+ metal ions in aqueous solutions was studied by batch experiment as a function of pH, contact time, temperature, and column techniques at 25.0 ∘ C and pH = 3. e highest rate of metal ions uptake was observed aer 18 h of shaking, and the uptake has increased with increasing pH and reached a maximum at pH = 3. Bentonite has shown high metal ion uptake capacity toward uranium(VI) than thorium(IV). Sorption data were evaluated according to the pseudo-second-order reaction kinetic. Sorption isotherms were studied at temperatures 25.0 ∘ C, 35.0 ∘ C, and 45.0 ∘ C. e Langmuir, Freundlich, and Dubinin-Radushkevich (D-R) sorption models equations were applied and the proper constants were derived. It was found that the sorption process is enthalpy driven for uranium(VI) and thorium(IV). Recovery of uranium(VI) and thorium(IV) ions aer sorption was carried out by treatment of the loaded bentonite with different concentrations of HNO 3 1.0 M, 0.5 M, 0.1 M, and 0.01 M. e best percent recovery for uranium(VI) and thorium(IV) was obtained when 1.0 M HNO 3 was used.

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Uranium(6+) sorption on montmorillonite: Experimental and surface complexation modeling study

Cited by 103 publications

References 33 publications

A thermal, sorptive and spectral study of HDTMA-bentonite loaded with uranyl phosphate

A thermal, sorptive and spectral study of HDTMA-bentonite loaded with uranyl phosphate

Uranium(VI) Adsorption and Surface Complexation Modeling onto Background Sediments from the F-Area Savannah River Site

Sorption of Uranium(VI) and Thorium(IV) by Jordanian Bentonite

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