Characteristics and Mechanism of Pb2+ Adsorption From Aqueous Solution Onto Biochar Derived From Microalgae and Chitosan-Modified Microalgae

Weigang Liu, Ke-lin Li, Xi Hu, Xinjiang Hu, Ruibin Zhang, Qi Li
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引用次数: 5

Abstract

With increasing aquatic heavy metal pollution and eutrophication, using algae to prepare novel adsorbent materials for remediating heavy metal pollution has recently attracted research attention worldwide. However, microalgae biochar exhibits poor adsorption capacity in certain conditions, and little is known regarding microalgae biochar modification using chitosan. Chitosan has been previously used to directly modify microalgae biochar; however, in this study, chitosan is used to modify algae powder used to prepare biochar. Therefore, in this study, chitosan was used as a microalgae biochar modifier to enhance its applicability and adsorption capacity. Accordingly, two new types of microalgae biochars, chitosan-biochar (CTS-BC) and biochar-chitosan (BC-CTS), were developed as an adsorbent material using Clostridium and adding chitosan as a modifier at different stages of its preparation. These developed microalgae biochars were characterized using Brunauer–Emmett–Teller surface area,X-ray photoelectron spectroscopy, Fourier transform infrared spectroscopy, and scanning electron microscopy. The adsorption processes of these biochars can be well described by a pseudo-second-order kinetic model. Pb2+ was dominantly adsorbed by microalgal biochar through chemisorption. Following chitosan modification, several mino, cyano, and aromatic ring groups were attached onto the surface of the microalgal biochar. The Pb2+ adsorption capacity of the chitosan-modified biochar was better than that of the unmodified biochar. The maximum Pb2+ adsorption capacity of CTS-BC under acidic conditions (pH = 5) was 9.41 mg g−1, whereas that of BC-CTS under alkaline conditions (pH = 9) was 9.94 mg g−1, both were higher than that of unmodified microalgae biochar under similar conditions. CTS-BC and BC-CTS possessed excellent stability and reusability for Pb(II) adsorption, the adsorption efficiency still remained above 50% even after three cycles. This study demonstrated that adsorbent materials having a stronger heavy-metal adsorption capacity can be prepared by adding chitosan during different stages of the microalgae biochar preparation process.
微藻及壳聚糖修饰微藻生物炭对Pb2+的吸附特性及机理
随着水体重金属污染和富营养化的日益严重,利用藻类制备新型吸附材料修复水体重金属污染已成为国内外研究热点。然而,微藻生物炭在某些条件下表现出较差的吸附能力,并且对壳聚糖改性微藻生物炭的研究还很少。壳聚糖曾被用于直接修饰微藻生物炭;然而,在本研究中,利用壳聚糖对用于制备生物炭的藻粉进行改性。因此,本研究采用壳聚糖作为微藻生物炭改性剂,提高其适用性和吸附能力。在此基础上,以梭菌为原料,在不同制备阶段添加壳聚糖作为改性剂,开发了壳聚糖-生物炭(CTS-BC)和生物炭-壳聚糖(BC-CTS)两种新型微藻生物炭。利用brunauer - emmet - teller比表面积、x射线光电子能谱、傅里叶变换红外光谱和扫描电镜对制备的微藻生物炭进行了表征。这些生物炭的吸附过程可以用拟二级动力学模型很好地描述。Pb2+主要通过化学吸附被微藻生物炭吸附。经壳聚糖修饰后,微藻生物炭表面附着了几个氨基、氰基和芳香基团。壳聚糖改性后的生物炭对Pb2+的吸附能力优于未改性的生物炭。CTS-BC在酸性条件(pH = 5)下对Pb2+的最大吸附量为9.41 mg g−1,在碱性条件(pH = 9)下对Pb2+的最大吸附量为9.94 mg g−1,均高于相同条件下未改性的微藻生物炭。CTS-BC和BC-CTS对Pb(II)的吸附具有良好的稳定性和可重复使用性,经过3次循环后吸附效率仍保持在50%以上。本研究表明,在微藻生物炭制备过程的不同阶段,添加壳聚糖可以制备出具有较强重金属吸附能力的吸附材料。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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