Copper and zinc sulfides bioleaching by an extremely thermophilic archaeon in high NaCl concentration

IF 3.7 3区生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Biochemical Engineering Journal Pub Date : 2024-09-24 DOI:10.1016/j.bej.2024.109509

Flávio Luiz Martins , Yago Costa Roberto , Versiane Albis Leão

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Abstract

Chloride bioleaching has received attention of several mineral processing industries, particularly in countries where there is scarcity of freshwater and only chloride-containing waters can be used. Therefore, the present work investigated the effect of NaCl (1.0 mol L⁻¹) on the bioleaching of three sulfide minerals: chalcopyrite, bornite, and sphalerite by the thermophilic archaea Sulfolobus acidocaldarius. Chalcopyrite dissolution was only 25 % in the biotic experiment in the absence of chloride, but reached 90 % in the presence of both microorganisms and chloride, while less than 60 % extraction was observed in the abiotic experiment with chloride. In the experiments of bornite bioleaching, 86 % and 77 % of copper were extracted in the biotic and abiotic tests with chloride, respectively. In the absence of NaCl, the biotic and abiotic experiments presented similar copper dissolution (∼35 %). Finally, bioleaching experiments carried out with sphalerite showed zinc extractions below 35 % in all conditions tested. The main contribution from the archaea was its ability to produce low concentrations of ferric ion, which was partially precipitated as jarosite, resulting in low redox potential values (< 450 mV vs. Ag/AgCl), and efficiently bioleached bornite and chalcopyrite. Furthermore, XRD and SEM-EDS analyses demonstrated that sphalerite was practically not leached while bornite was transformed into new copper sulfide phases (CuS and Cu₃FeS₄). Jarosite and elemental sulfur were products of chalcopyrite and bornite bioleaching in the presence of chloride.

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高浓度氯化钠条件下极嗜热古生物对硫化铜和硫化锌的生物浸出作用

氯化物生物浸出已受到多个矿物加工行业的关注，尤其是在淡水匮乏且只能使用含氯化物水的国家。因此，本研究调查了 NaCl（1.0 mol L-1）对嗜热古菌 Sulfolobus acidocaldarius 对黄铜矿、辉锑矿和闪锌矿这三种硫化矿物进行生物浸出的影响。在无氯化物的生物实验中，黄铜矿的溶解度仅为 25%，但在微生物和氯化物同时存在的情况下，溶解度达到了 90%，而在有氯化物的非生物实验中，黄铜矿的提取率不到 60%。在波来石生物浸出实验中，在有氯化物的生物和非生物试验中，铜的萃取率分别为 86% 和 77%。在没有氯化钠的情况下，生物实验和非生物实验的铜溶解度相似（35%）。最后，用闪锌矿进行的生物浸出实验表明，在所有测试条件下，锌的提取率都低于 35%。古细菌的主要贡献在于其产生低浓度铁离子的能力，铁离子部分沉淀为绿泥石，导致低氧化还原电位值（< 450 mV vs. Ag/AgCl），并有效地生物浸蚀了辉铜矿和黄铜矿。此外，XRD 和 SEM-EDS 分析表明，闪锌矿几乎没有被浸出，而辉铜矿则转变成了新的硫化铜相（CuS 和 Cu3FeS4）。箭石和元素硫是黄铜矿和辉铜矿在氯化物存在下生物浸出的产物。

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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来源期刊

Biochemical Engineering Journal 工程技术-工程：化工

CiteScore

7.10

自引率

5.10%

发文量

380

审稿时长

34 days

期刊介绍： The Biochemical Engineering Journal aims to promote progress in the crucial chemical engineering aspects of the development of biological processes associated with everything from raw materials preparation to product recovery relevant to industries as diverse as medical/healthcare, industrial biotechnology, and environmental biotechnology. The Journal welcomes full length original research papers, short communications, and review papers* in the following research fields: Biocatalysis (enzyme or microbial) and biotransformations, including immobilized biocatalyst preparation and kinetics Biosensors and Biodevices including biofabrication and novel fuel cell development Bioseparations including scale-up and protein refolding/renaturation Environmental Bioengineering including bioconversion, bioremediation, and microbial fuel cells Bioreactor Systems including characterization, optimization and scale-up Bioresources and Biorefinery Engineering including biomass conversion, biofuels, bioenergy, and optimization Industrial Biotechnology including specialty chemicals, platform chemicals and neutraceuticals Biomaterials and Tissue Engineering including bioartificial organs, cell encapsulation, and controlled release Cell Culture Engineering (plant, animal or insect cells) including viral vectors, monoclonal antibodies, recombinant proteins, vaccines, and secondary metabolites Cell Therapies and Stem Cells including pluripotent, mesenchymal and hematopoietic stem cells; immunotherapies; tissue-specific differentiation; and cryopreservation Metabolic Engineering, Systems and Synthetic Biology including OMICS, bioinformatics, in silico biology, and metabolic flux analysis Protein Engineering including enzyme engineering and directed evolution.