Uranium sorption on oxyhydroxide minerals by surface complexation and precipitation

“…The adsorption capacities of the different adsorbents are listed in Table S3 (Supporting Information). Among the adsorbents reported in Table S3, eight adsorbents (γ-AlOOH, UiO-66-PO-Ph), phosphate rock apatite (PRA), chitosan-modified phosphate rock (CPR), Na-attapulgite, zeolite NaY, aerated zone soil, and P–C4 (PPN-6-CH 2 P + (C 4 H 9 ) 3 Cl – ) were used to adsorb U­(VI) at different conditions. ,,,,,,, The maximum adsorption capacities of UiO-66-PO-Ph, Na-attapulgite, and phosphate rock apatite (PRA) were 111.9, 0.19, and 0.2021 mg/g to U­(VI) ions in pH 3, pH 4.4, and pH 3.88, respectively. ,, The maximum adsorption capacities of zeolite NaY and CPR for U­(VI) ions at pH 2.5 were 14.05 and 8.06 mg/g, respectively. , Aerated zone soil showed the maximum adsorption capacity of 1.98 mg/g at pH 7, with the U­(VI) content of 10 mg/L, 24 h, 298 K . Compared to the six reported adsorbents, γ-AlOOH showed a higher U­(VI) adsorption capacity of 19.8 mg/g in alkaline solution than those of other adsorbents.…”

“…To date, there are various methods for separating U­(VI) ions from aqueous solution, mainly involving adsorption, − solvent-extraction, − chemical precipitation, , membrane separation, , and so on. For example, Wang et al showed that the sorption capacity of boehmite for U­(VI) was 2.78 mg/g (pH 5 ± 0.1). de Moraes et al stated that the removal yield of U­(VI) via hematite was nearly 100% in slightly acidic mine wastewaters (pH = 6).…”

“…To date, there are various methods for separating U(VI) ions from aqueous solution, mainly involving adsorption, 9−12 solvent-extraction, 13−16 chemical precipitation, 17,18 membrane separation, 19,20 and so on. For example, Wang et al 11 showed that the sorption capacity of boehmite for U(VI) was 2.78 mg/ g (pH 5 ± 0.1). de Moraes et al 21 stated that the removal yield of U(VI) via hematite was nearly 100% in slightly acidic mine wastewaters (pH = 6).…”

Adsorption of Low-Concentrated U(VI) on a Preferable Crystalline Boehmite (γ-AlOOH) in Alkaline Conditions

“…The adsorption capacities of the different adsorbents are listed in Table S3 (Supporting Information). Among the adsorbents reported in Table S3, eight adsorbents (γ-AlOOH, UiO-66-PO-Ph), phosphate rock apatite (PRA), chitosan-modified phosphate rock (CPR), Na-attapulgite, zeolite NaY, aerated zone soil, and P–C4 (PPN-6-CH 2 P + (C 4 H 9 ) 3 Cl – ) were used to adsorb U­(VI) at different conditions. ,,,,,,, The maximum adsorption capacities of UiO-66-PO-Ph, Na-attapulgite, and phosphate rock apatite (PRA) were 111.9, 0.19, and 0.2021 mg/g to U­(VI) ions in pH 3, pH 4.4, and pH 3.88, respectively. ,, The maximum adsorption capacities of zeolite NaY and CPR for U­(VI) ions at pH 2.5 were 14.05 and 8.06 mg/g, respectively. , Aerated zone soil showed the maximum adsorption capacity of 1.98 mg/g at pH 7, with the U­(VI) content of 10 mg/L, 24 h, 298 K . Compared to the six reported adsorbents, γ-AlOOH showed a higher U­(VI) adsorption capacity of 19.8 mg/g in alkaline solution than those of other adsorbents.…”

“…To date, there are various methods for separating U­(VI) ions from aqueous solution, mainly involving adsorption, − solvent-extraction, − chemical precipitation, , membrane separation, , and so on. For example, Wang et al showed that the sorption capacity of boehmite for U­(VI) was 2.78 mg/g (pH 5 ± 0.1). de Moraes et al stated that the removal yield of U­(VI) via hematite was nearly 100% in slightly acidic mine wastewaters (pH = 6).…”

“…To date, there are various methods for separating U(VI) ions from aqueous solution, mainly involving adsorption, 9−12 solvent-extraction, 13−16 chemical precipitation, 17,18 membrane separation, 19,20 and so on. For example, Wang et al 11 showed that the sorption capacity of boehmite for U(VI) was 2.78 mg/ g (pH 5 ± 0.1). de Moraes et al 21 stated that the removal yield of U(VI) via hematite was nearly 100% in slightly acidic mine wastewaters (pH = 6).…”

Adsorption of Low-Concentrated U(VI) on a Preferable Crystalline Boehmite (γ-AlOOH) in Alkaline Conditions

“…At a pH of 6.0–8.0 (stage II), the gradual appearance of negatively charged U( vi ) species (UO 2 ) 3 (OH) 7 − , UO 2 (OH) 3 − and UO 2 (OH) 4 2− increased the electrostatic attraction and the –OH group on the surface of NiAl and ZnNiAl could complex with UO 2 2+ , as well as the UO 2 CO 3 precipitate was formed owing to CO 3 2− intercalation (urea pyrolysis). 34,35 At a pH > 8.0 (stage III), the concentration of OH − increased and the surface of NiAl and ZnNiAl was negatively charged, therefore, the adsorption capacity decreased due to electrostatic repulsion. Subsequently, the effects of different concentrations of NaNO 3 (0001, 0.01, and 0.1 mol L −1 ) on U( vi ) adsorption were investigated.…”

“…At a pH of 2.0-6.0 (stage I), U(VI) presented as positive species of UO was formed owing to CO 3 2− intercalation (urea pyrolysis). 34,35 At a pH > 8.0 (stage III), the concentration of OH − increased and the surface of NiAl and ZnNiAl was negatively charged, therefore, the adsorption capacity decreased due to electrostatic repulsion. Subsequently, the effects of different concentrations of NaNO 3 (0001, 0.01, and 0.1 mol L −1 ) on U(VI) adsorption were investigated.…”

Adsorption-photoreduction behaviors and mechanisms of layered double hydroxide loaded on uranium(vi) removal

Uranium in natural waters and the environment: Distribution, speciation and impact