Calcium alginate-biochar composite immobilized A. ferrooxidans effectively removes sulfate and ferric iron from acid mine drainage.

IF 8 2区环境科学与生态学 Q1 ENVIRONMENTAL SCIENCES

Journal of Environmental Management Pub Date : 2024-11-11 DOI:10.1016/j.jenvman.2024.123227

Rui Li, Bing Wang, Bin Gao, Lei Li, Pan Wu, Xueyang Zhang, Miao Chen, Qianwei Feng

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引用次数: 0

Abstract

Bioremediation has been applied in the treatment of acid mine drainage (AMD), but high levels of sulfate (SO₄^2-) and ferric iron (Fe³⁺) in AMD often affect microbial activity. A novel biochar-microorganism composite (I-CMR600) was developed by alginate gel-embedding method to improve the tolerance of microorganisms and the removal effects of SO₄^2- and Fe³⁺ in AMD, and its removal mechanism and biological behavior were explored in this study. The removal performance of I-CMR600 under different influencing factors was studied by batch adsorption experiments. The removal mechanisms and biotransformation of SO₄^2- and Fe³⁺ were explored through different adsorption models combined with physicochemical characterizations. The results showed that A. ferroxidans secreted extracellular polymers to enhance the removal of contaminants, and high concentrations (>400 mg/L) of SO₄^2- and Fe³⁺ inhibited the activity of microorganisms. The Langmuir maximum adsorption capacities of I-CMR600 for SO₄^2- and Fe³⁺ were 32.85 and 63.53 mg/g, respectively. The effects of A. ferroxidans on SO₄^2- and Fe³⁺ were mainly through promoting their biotransformation, the adhesion of A. ferroxidans, and the complexation of secreted extracellular polymers with pollutants. I-CMR600 showed good reusability and promising potential for practical application in actual AMD. This study demonstrates that I-CMR600 is a promising biosorbent, providing a new avenue for removing SO₄^2- and Fe³⁺ from AMD.

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海藻酸钙-生物炭复合固定铁锈酸酵母菌可有效去除酸性矿井排水中的硫酸盐和铁。

生物修复技术已被应用于酸性矿井排水（AMD）的处理，但 AMD 中高浓度的硫酸盐（SO42-）和铁（Fe3+）往往会影响微生物的活性。本研究采用海藻酸凝胶包埋法研制了一种新型生物炭-微生物复合材料（I-CMR600），以提高微生物的耐受性和对 AMD 中 SO42- 和 Fe3+ 的去除效果，并探讨了其去除机理和生物行为。通过批次吸附实验研究了 I-CMR600 在不同影响因素下的去除性能。通过不同的吸附模型并结合物理化学特征，探讨了 SO42- 和 Fe3+ 的去除机理和生物转化。结果表明，铁锈酸酵母菌分泌胞外聚合物来提高污染物的去除率，而高浓度（>400 mg/L）的 SO42- 和 Fe3+ 会抑制微生物的活性。I-CMR600 对 SO42- 和 Fe3+ 的朗缪尔最大吸附容量分别为 32.85 和 63.53 mg/g。阿魏化石菌对 SO42- 和 Fe3+ 的影响主要通过促进它们的生物转化、阿魏化石菌的粘附以及分泌的胞外聚合物与污染物的络合。I-CMR600 显示出良好的重复使用性和在实际 AMD 中的实际应用潜力。这项研究表明，I-CMR600 是一种前景广阔的生物吸附剂，为去除 AMD 中的 SO42- 和 Fe3+ 提供了一条新途径。

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来源期刊

Journal of Environmental Management 环境科学-环境科学

CiteScore

13.70

自引率

5.70%

发文量

2477

审稿时长

84 days

期刊介绍： The Journal of Environmental Management is a journal for the publication of peer reviewed, original research for all aspects of management and the managed use of the environment, both natural and man-made.Critical review articles are also welcome; submission of these is strongly encouraged.