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Mechanistic insights into radium adsorption on montmorillonite: DFT and
experimental studies (2025) Jaeeun Kang, Ina Park, Ji Hoon Shim, Duck Young Kim, Wooyong Um Applied Surface Science Volume 703, 15 September 2025, 163406 DOI: https://doi.org/10.1016/j.apsusc.2025.163406 Abstract
Radium (Ra) released from spent nuclear fuel poses a challenge due to its long half-life (1600 years) and
radiological hazard, but its rarity limits experimental studies. This study explores the Ra adsorption mechanism
on montmorillonite, a key bentonite component in engineered barriers, using theoretical calculations and ex�periments. Theoretical results identified three stable Ra-complexes in aqueous solutions with different water and
hydroxyl coordination numbers. Our findings demonstrate that Ra(OH)2(H2O)4 forms inner-sphere complexes on
(0 0 1) surfaces, exhibiting greater stability than Ra2+ and [Ra(H2O)8]
2+ species. On the (0 1 0) surface, both
Ra2+ and Ra(OH)2(H2O)4 form inner-sphere complexes with stronger adsorption compared to [Ra(H2O)8]
2+,
which adsorbs through weaker hydrogen bonding. Additionally, Ra(OH)2(H2O)4 adsorbed on the (0 1 0) surface
showed the most stable form on the deprotonated surface at high pH. The stability of Ra adsorption in mont�morillonite was also effectively demonstrated by charge transfer and density-of-states analysis. Furthermore, Ra
batch adsorption experiments confirmed that Ra adsorption followed a linear isotherm, and pH-dependent ex�periments showed that Ra uptake was highest at high pH conditions, in agreement with theoretical results. These
observations suggest that engineered barriers may mitigate Ra transport in deep disposal repositories subject to
high pH induced by concrete and rock.
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