基于生命周期评估和环境安全分析的生物炭-细菌耦合系统增强了苯酚废水的生物修复能力。

Xuejiao An, Yanlin Wang, Chenglong Yu, Xiaojing Hu
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摘要

酚类废水会对水和土壤生态系统造成严重污染,因此必须对其进行有效处理。使用生物炭固定化功能微生物可以创新性地、可持续地解决现有问题。在本研究中,我们利用响应面方法(RSM)结合生命周期评估(LCA),通过分离出的新型耐碱嗜热菌株卤代不耐热芽孢杆菌(Bacillus halotolerans ACY)来提高苯酚的生物降解率。生物信息学分析揭示了 ACY 适应恶劣环境的遗传基础。研究了不同热解温度(300-700 ℃)下产生的猪粪生物炭(PMB)的特性,并进行了吸附实验。在碱性和高污染负荷下,将降解苯酚的 ACY 固定在 PMB600 上,促进了苯酚的去除和对极端环境的耐受性,在实际苯酚废水中 7d 苯酚去除率达到 99.5%,与单独使用 PMB(50.6%)和游离菌(80.5%)相比有所提高。扫描电子显微镜(SEM)和傅立叶变换红外光谱仪(FTIR)的观察结果表明,细菌在 PMB600 上的固定化取得了成功。可重复使用性和经济成本研究进一步证明 PMB600 是一种用于废水处理的优良载体。LC-MS、毒理学和碳足迹分析表明,细菌代谢与吸附对苯酚的去除具有协同作用,而生物降解则对固定化细菌系统产生了主要影响。这项研究为处理苯酚废水提供了一种环保而有效的方法。
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Biochar-bacteria coupling system enhanced the bioremediation of phenol wastewater-based on life cycle assessment and environmental safety analysis.

The efficient treatment of phenol wastewater is of great necessity since it induces serious pollution of water and soil ecosystems. Using biochar-immobilized functional microorganisms can innovatively and sustainably deal with the existing problem. In this study, we utilized response surface methodology (RSM) combined with life cycle assessment (LCA) to improve phenol biodegradation rate through a novel separated alkali-resistant and thermophilic strain Bacillus halotolerans ACY. Bioinformatic analysis revealed the genetic foundation of ACY to adapt to harsh environments. The characteristics of pig manure biochar (PMB) produced at varying pyrolysis temperatures (300-700 ℃) and adsorption experiment were investigated, immobilization of the phenol-degrading ACY on PMB600 under alkaline and high pollution load promoted phenol removal and extreme environment resistance, and the phenol removal rate reached 99.5 % in 7d in actual phenol wastewater, which increased compared with those achieved by PMB (50.6 %) and free bacteria (80.5 %) alone. Scanning Electron Microscope (SEM) and Fourier transform infrared spectrometry (FTIR) observations indicated the successful bacterial immobilization on PMB600. Reusability and economic cost study further demonstrated PMB600 as an excellent carrier for wastewater treatment. LC-MS, toxicology and carbon footprint analyses demonstrated that bacterial metabolism exerted synergy with adsorption for phenol removal, while biodegradation exerted the predominant impact on the immobilized bacterial system. This study provides an eco-friendly and effective approach to treat phenol wastewater.

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