Sulfate Reduction in the Hydrogen‐Based Membrane Biofilm Reactor Receiving Calcium Reduced Phosphogypsum Water

IF 3.6 2区生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Biotechnology and Bioengineering Pub Date : 2025-07-05 DOI:10.1002/bit.70015

Anwar Alsanea, Ayoub Bounaga, Karim Lyamlouli, Youssef Zeroual, Rachid Boulif, Chen Zhou, Bruce Rittmann

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引用次数: 0

Abstract

Phosphogypsum (PG), a byproduct of phosphate mining, contains sulfate that can be leached and converted to elemental sulfur, thus offering a sustainable opportunity to recover sulfur (S) as a step toward a circular economy. Calcium, at ~15 mM in PG leachate, creates inorganic precipitation that interferes with biological sulfate reduction, the first step of S recovery. Here, we evaluated the effectiveness of using cation‐exchange to lower the calcium concentration in water‐leached PG (PG water) delivered to a H2‐based membrane biofilm reactor (H2‐MBfR) employed to reduce sulfate to sulfide. A high sulfate flux (1 gS/m2‐day) and 65% sulfate reduction were achieved despite a high pH (10) resulting from base production during sulfate reduction. However, soluble sulfide was only 20% of the reduced S, possibly due to precipitation of sulfide, iron, and phosphate, and alkalinity analysis revealed possible formation of polysulfides. Shallow metagenomics of the biofilm documented that Desulfomicrobium was the dominant sulfate‐reducing bacterium, while Thauera, a mixotroph capable of sulfate reduction and sulfide oxidation, also was an important genus. The metagenomics also revealed the presence of methanogens and acetogens that competed for H2 and CO2. Although calcium removal from PG water improved sulfate reduction and reduced inorganic precipitation in the H2‐MBfR, soluble sulfide generation must be improved by supplying sufficient CO2 to moderate pH increase due to sulfate reduction and by controlling the H2‐delivery capacity to limit methanogens and acetogens.

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接受钙还原磷石膏水的氢基膜生物膜反应器中的硫酸盐还原

磷石膏（PG）是磷矿开采的副产品，含有硫酸盐，可以浸出并转化为单质硫，因此提供了一个可持续的机会来回收硫，作为迈向循环经济的一步。PG渗滤液中~15 mM的钙会产生无机沉淀，干扰硫酸盐的生物还原，这是S回收的第一步。在这里，我们评估了使用阳离子交换来降低水浸PG （PG水）中钙浓度的有效性，PG水被输送到H2基膜生物膜反应器（H2 - MBfR）中，用于将硫酸盐还原为硫化物。尽管硫酸盐还原过程中碱生成的pH值很高（10），但仍实现了高硫酸盐通量（1 gS/m2 - day）和65%的硫酸盐还原。然而，可溶性硫化物仅为还原S的20%，可能是由于硫化物、铁和磷酸盐的沉淀，碱度分析显示可能形成了多硫化物。生物膜的浅宏基因组分析表明，desulfomicroum是主要的硫酸盐还原菌，而Thauera是一种能够硫酸盐还原和硫化物氧化的混合营养菌，也是一个重要的属。宏基因组学还揭示了产甲烷菌和产乙菌的存在，这些产甲烷菌和产乙菌竞争H2和CO2。虽然从PG水中去除钙可以改善硫酸盐还原，减少H2 - MBfR中的无机沉淀，但必须通过提供足够的CO2来调节硫酸盐还原引起的pH升高，并通过控制H2的输送能力来限制产甲烷菌和产乙菌，才能改善可溶性硫化物的生成。

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

Biotechnology and Bioengineering 工程技术-生物工程与应用微生物

CiteScore

7.90

自引率

5.30%

发文量

280

审稿时长

2.1 months

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