Three-dimensional-printed calcium alginate/graphene oxide porous adsorbent with super-high lead ion adsorption ability in aqueous solution

•The prepared 3D CA/GO with a hierarchical macroporous structure and a light weight.•3D CA/GO has enhanced adsorption capacity in aqueous solution (490.2 mg/g, pH = 3.0).•3D CA/GO presented a good structural stability in aqueous solution.•Pb(II) can be recovered, concentrated and reused by elution w...

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Published in:Separation and purification technology 2023-12, Vol.326, p.124757, Article 124757
Main Authors: Wang, Na, Song, Fuxiang, Niu, Yuxin, Chen, Wenjie, Liu, Bin, Xie, Weibo
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Language:English
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3D printing CA/GO
Adsorption
Pb(II)
Porous structure
Wastewater
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Song, Fuxiang
Niu, Yuxin
Chen, Wenjie
Liu, Bin
Xie, Weibo
description •The prepared 3D CA/GO with a hierarchical macroporous structure and a light weight.•3D CA/GO has enhanced adsorption capacity in aqueous solution (490.2 mg/g, pH = 3.0).•3D CA/GO presented a good structural stability in aqueous solution.•Pb(II) can be recovered, concentrated and reused by elution with hydrochloric acid.•The selective adsorption of Pb(II) by 3D CA/GO was 99.8%. Using three-dimensional (3D) printing technology, a 3D calcium alginate/graphene oxide (3D CA/GO) adsorbent, with a hierarchical macroporous structure, was successfully constructed. Owing to the optimized construction process, the 3D CA/GO showed an enhanced adsorption capacity (490.2 mg/g at pH = 3.0) for lead (Pb(II)) in aqueous solution, which was two times higher than reported in the literature). Meanwhile, the selective adsorption ratio of 3D CA/GO for Pb(II) reached 99.8% when positive ions occurred. In addition, after eight adsorption–desorption cycles, the adsorption capacity did not experience a significant decrease and the structure remained stable. Meanwhile, the adsorbed Pb(II) could be eluted by hydrochloric acid. Moreover, through characterization analysis and Ca(II) releasing experiment, we confirmed that the adsorption mechanism of 3D CA/GO consisted of electrostatic interactions, ion exchange and chelation. According to the actual application experimental, the waste water of medical environment was chosen, and the 3D CA/GO was verified as capable of removing and recycling Pb(II). The immersion experiment using simulation wastewater solution containing heavy metal ions also indicated that 3D CA/GO could maintain structural stability and sustain its adsorption capacity. The excellent structural stability, strong adsorption capacity, and outstanding selective adsorption capacity for 3D CA/GO were attributed to the controllable construction and optimized structure of hierarchical macroporous materials by 3D printing technology.
doi_str_mv 10.1016/j.seppur.2023.124757
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Using three-dimensional (3D) printing technology, a 3D calcium alginate/graphene oxide (3D CA/GO) adsorbent, with a hierarchical macroporous structure, was successfully constructed. Owing to the optimized construction process, the 3D CA/GO showed an enhanced adsorption capacity (490.2 mg/g at pH = 3.0) for lead (Pb(II)) in aqueous solution, which was two times higher than reported in the literature). Meanwhile, the selective adsorption ratio of 3D CA/GO for Pb(II) reached 99.8% when positive ions occurred. In addition, after eight adsorption–desorption cycles, the adsorption capacity did not experience a significant decrease and the structure remained stable. Meanwhile, the adsorbed Pb(II) could be eluted by hydrochloric acid. Moreover, through characterization analysis and Ca(II) releasing experiment, we confirmed that the adsorption mechanism of 3D CA/GO consisted of electrostatic interactions, ion exchange and chelation. According to the actual application experimental, the waste water of medical environment was chosen, and the 3D CA/GO was verified as capable of removing and recycling Pb(II). The immersion experiment using simulation wastewater solution containing heavy metal ions also indicated that 3D CA/GO could maintain structural stability and sustain its adsorption capacity. 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Using three-dimensional (3D) printing technology, a 3D calcium alginate/graphene oxide (3D CA/GO) adsorbent, with a hierarchical macroporous structure, was successfully constructed. Owing to the optimized construction process, the 3D CA/GO showed an enhanced adsorption capacity (490.2 mg/g at pH = 3.0) for lead (Pb(II)) in aqueous solution, which was two times higher than reported in the literature). Meanwhile, the selective adsorption ratio of 3D CA/GO for Pb(II) reached 99.8% when positive ions occurred. In addition, after eight adsorption–desorption cycles, the adsorption capacity did not experience a significant decrease and the structure remained stable. Meanwhile, the adsorbed Pb(II) could be eluted by hydrochloric acid. Moreover, through characterization analysis and Ca(II) releasing experiment, we confirmed that the adsorption mechanism of 3D CA/GO consisted of electrostatic interactions, ion exchange and chelation. 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Using three-dimensional (3D) printing technology, a 3D calcium alginate/graphene oxide (3D CA/GO) adsorbent, with a hierarchical macroporous structure, was successfully constructed. Owing to the optimized construction process, the 3D CA/GO showed an enhanced adsorption capacity (490.2 mg/g at pH = 3.0) for lead (Pb(II)) in aqueous solution, which was two times higher than reported in the literature). Meanwhile, the selective adsorption ratio of 3D CA/GO for Pb(II) reached 99.8% when positive ions occurred. In addition, after eight adsorption–desorption cycles, the adsorption capacity did not experience a significant decrease and the structure remained stable. Meanwhile, the adsorbed Pb(II) could be eluted by hydrochloric acid. Moreover, through characterization analysis and Ca(II) releasing experiment, we confirmed that the adsorption mechanism of 3D CA/GO consisted of electrostatic interactions, ion exchange and chelation. According to the actual application experimental, the waste water of medical environment was chosen, and the 3D CA/GO was verified as capable of removing and recycling Pb(II). The immersion experiment using simulation wastewater solution containing heavy metal ions also indicated that 3D CA/GO could maintain structural stability and sustain its adsorption capacity. The excellent structural stability, strong adsorption capacity, and outstanding selective adsorption capacity for 3D CA/GO were attributed to the controllable construction and optimized structure of hierarchical macroporous materials by 3D printing technology.</abstract><pub>Elsevier B.V</pub><doi>10.1016/j.seppur.2023.124757</doi><oa>free_for_read</oa></addata></record>
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subjects 3D printing CA/GO
Adsorption
Pb(II)
Porous structure
Wastewater
title Three-dimensional-printed calcium alginate/graphene oxide porous adsorbent with super-high lead ion adsorption ability in aqueous solution
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