Ultralight carbon aerogel composites derived from MOFs and cross-linked chitosan: Synthesis, characterization, and U(VI) adsorption

Ultralight carbon aerogel composites derived from MOFs and cross-linked chitosan: Synthesis, characterization, and U(VI) adsorption

[Display omitted] •A phosphorylation-modified ultralight carbon aerogel composite (CUCA/MPCs-PO4) was successfully prepared by a simple strategy.•CUCA/2MPCs-PO4 exhibited a maximum adsorption capacity of 592.0 mg/g for U(VI).•An actual wastewater treatment using CUCA/2MPCs-PO4 achieved 92.2 % U(VI)...

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Bibliographic Details
Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Vol. 455; p. 140749
Main Authors: Sun, Yanbing, Chen, Jianfa, Kang, Yixiao, Zhang, Haoyan, Ge, Yulin, Yuan, Nan, Xing, Yubo, Ma, Wei, Yang, Zhen, Zou, Liping, Lu, Liang
Format: Journal Article
Language:English
Published: Elsevier B.V 01-01-2023
Subjects:
Adsorption
Carbon aerogel
Chitosan
Phosphorylation
Uranium
Wastewater
Phosphorylation
Uranium
Chitosan
Adsorption
Wastewater
Carbon aerogel
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Summary:[Display omitted] •A phosphorylation-modified ultralight carbon aerogel composite (CUCA/MPCs-PO4) was successfully prepared by a simple strategy.•CUCA/2MPCs-PO4 exhibited a maximum adsorption capacity of 592.0 mg/g for U(VI).•An actual wastewater treatment using CUCA/2MPCs-PO4 achieved 92.2 % U(VI) removal.•The mechanism of U(VI) adsorption is electrostatic attraction and the chelation by CO and PO bonding. An environmentally friendly and cost-effective adsorbent for removing U(VI) from radioactive wastewater is of significant importance for protecting the environment. In this work, we successfully prepared an ultralight carbon aerogel material (CUCA/MPCs) derived from chitosan and MOFs, and synthesized an adsorbent (CUCA/MPCs-PO4) with a high chelation ability to U(VI) through phosphorylation modification. Various characterization techniques were used to characterize the microscopic morphology and crystallographic structure of the adsorbents. During the batch experiments, it was determined that the optimum pH for the adsorbents for U(VI) was 6.5. According to the linear Langmuir isotherm model and pseudo-second-order kinetic model, U(VI) adsorption on the adsorbent is a monolayer chemisorption reaction. The fitted maximum adsorption capacities of CUCA-PO4, CUCA/1MPCs-PO4, and CUCA/2MPCs-PO4 for U(VI) were 357.1 mg/g, 526.3 mg/g, and 592.0 mg/g, respectively. Furthermore, the three adsorbents showed good recyclability, maintaining 79.0 %, 77.4 %, and 82.2 % of the initial adsorption capacity after eight cycles, respectively. The results of actual U(VI) waste adsorption experiments showed that CUCA/2MPCs-PO4 achieved 92.2 % removal of U(VI), showing good potential for practical applications. Finally, the possible adsorption mechanism between U(VI) and adsorbent was discussed in the context of experimental and characterization results. Overall, this study provides a valuable research idea for the treatment of radioactive wastewater containing U(VI).
ISSN:1385-8947
DOI:10.1016/j.cej.2022.140749