Highly efficient and selective capture of uranium from groundwater by using an ultrathin 2D MOF nanosheet with pocket-like cavities

• Published in: Separation and purification technology Vol. 341; p. 126892
• Main Authors: Yao, Meng-Ru, Wang, Zi-Yan, Geng, Ao-Chen, Wu, Kang-Yu, Luo, Mei-Jiao, Li, Zong-Hao, Sun, Yuan-Qin, Gao, Ming-Jun, Yu, Cai-Xia, Liu, Lei-Lei
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 09.08.2024
• Subjects: Calixarene; Efficient and selective capture; Pocket-like cavity; Ultrathin 2D MOF nanosheet; Uranium; Uranium; Calixarene; Efficient and selective capture; Ultrathin 2D MOF nanosheet; Pocket-like cavity
• ISSN: 1383-5866; 1873-3794
• DOI: 10.1016/j.seppur.2024.126892

[Display omitted] •An ultrathin MOF nanosheet with cavity structures was fabricated for uranium removal.•It has excellent selectivity for uranium in the presence of multiple coexisting ions.•The selectivity coefficient (SU/M) can reach as high as 3.69 × 105.•The MOF nanosheet exhibited extremely high anti-interference capability.•Superb adsorption rate (<20 min) and removal efficiency for uranium (>98 %) were reached in groundwater. Highly efficient and selective removal of uranium from aqueous media is crucial for the sustained development of nuclear energy. Herein, we utilized the intrinsic advantages of two-dimensional (2D) metal–organic frameworks (MOFs) and developed an ultrathin 2D MOF nanosheet with cavity structure. The preconcentration of the pocket-like cavities on the MOF nanosheet and sufficient interactions with the adsorption sites in the cavity structure realized highly efficient removal of uranium from water. Even in the low concentration range of 0.05–1 ppm, relatively high removal ratios and fast adsorption kinetics still can be achieved. Additionally, the MOF nanosheet exhibited extremely high anti-interference capability, which can efficiently reduce uranium pollution (0.05–1 ppm) in acid groundwater to the safe level (≤30 ppb) recommended by World Health Organization, and the removal performance was comparable to that in deionized water. The adsorption mechanism was thoroughly studied by Fourier transform infrared analysis, X-ray photoelectron spectroscopy, and density functional theory calculations, which revealed that the interactions between uranyl ions and the carboxylate groups dominated uranium adsorption, and the H-bonding interactions in the pocket-like cavities played an important role in uranium extraction.