用于重金属离子修复的纤维焊接 EDTA 改性纤维素

IF 6.2 Q1 CHEMISTRY, APPLIED
Christopher D. Stachurski, Nathaniel E. Larm, Anders J. Gulbrandson, Paul C. Trulove, David P. Durkin
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引用次数: 0

摘要

乙二胺四乙酸(EDTA)是一种著名的金属螯合剂,也是一种极具吸引力的配体,可用于共价改性吸附剂,以进行生物修复。纤维素是一种天然生物聚合物,作为一种价格低廉、资源丰富、生物相容性好的支架,在 EDTA 促进的环境修复方面具有巨大潜力;不过,要对材料进行充分的化学改性,需要对其进行预处理。本研究采用天然纤维焊接(NFW)技术制备用于 EDTA 功能化的商品棉 Aida 布。天然纤维焊接后,每克吸附剂中的棉质支架被共价改性了多达 0.56 mmol EDTA,比原生材料增加了近 2.5 倍。对焊接的 EDTA 改性基质进行了针对钴的定性测试和针对镍的定量测试,结果表明每克吸附剂的平衡结合能力(qe)高达 46 毫克金属,与过去 EDTA 改性纤维素工作中报告的能力相当。此外,吸附材料可通过弱酸处理再生,而 qe 不会显著降低。与对照组不同的是,纤维焊接的 EDTA-Aida 在经过 3 次螯合循环后也不会磨损,这表明 NFW 处理增强了织物的坚固性。总之,NFW 提供了一种新方法,可将市售的可持续生物材料转化为用于环境修复的坚固吸附剂。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Fiber welded EDTA-modified cellulose for remediation of heavy metal ions

Fiber welded EDTA-modified cellulose for remediation of heavy metal ions

Ethylenediaminetetraacetic acid (EDTA) is a well-known metal chelator and an attractive ligand for covalently modifying adsorbents for bioremediation. Cellulose, a naturally occurring biopolymer, has immense potential as an inexpensive, earth abundant, biocompatible scaffold for EDTA-facilitated environmental remediation; however, pretreatment of the material is required to achieve sufficient degrees of chemical modification. In this study, Natural Fiber Welding (NFW) is used to prepare commercial cotton Aida cloth for EDTA functionalization. Following NFW, the cotton scaffold was covalently modified with up to 0.56 mmol of EDTA per gram of adsorbent, a nearly 2.5-fold increase over native material. The welded EDTA-modified substrates were tested qualitatively against cobalt and quantitatively against nickel, reaching equilibrium binding capacities (qe) of up to 46 mg metal per g of adsorbent, on par with capacities reported from past work on EDTA-modified cellulose. In addition, adsorbent material could be regenerated using mild acid treatment with no significant loss in qe. Unlike the controls, the fiber-welded EDTA-Aida did not fray even after 3 chelation cycles, indicating enhanced textile robustness afforded through NFW treatment. Overall, NFW offers a new approach to converting commercially available, sustainable biomaterials into robust adsorbents for environmental remediation.

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CiteScore
8.70
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