A novel strategy for waste activated sludge treatment: Recovery of structural extracellular polymeric substances and fermentative production of volatile fatty acids

IF 11.4 1区环境科学与生态学 Q1 ENGINEERING, ENVIRONMENTAL

Water Research Pub Date : 2024-09-08 DOI:10.1016/j.watres.2024.122421

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引用次数: 0

Abstract

Structural extracellular polymeric substances (SEPS) as valuable biopolymers, can be extracted from waste activated sludge (WAS). However, the extraction yield is typically low, and detailed information on SEPS characterizations, as well as proper treatment of the sludge after SEPS extraction, remains limited. This study aimed to optimize the conditions of heating-Na₂CO₃ extraction process to increase the yield of SEPS extracted from WAS. Subsequently, SEPS were characterized, and, for the first time, insights into their protein composition were uncovered by using proteomics. A maximum SEPS yield of 209 mg g^-1 volatile solid (VS) was obtained under optimal conditions: temperature of 90 °C, heating time of 60 min, Na⁺ dosage of 8.0 mmol/g VS, and pH required to precipitation of 4.0, which was comparable to that from the aerobic granular sludge reported in literature. Proteomics analysis unveiled that the proteins in SEPS primarily originated from microorganisms involved in nitrogen fixation and organic matter degradation, including their intracellular and membrane-associated regions. These proteins exhibited various catalytic activities and played crucial roles in aggregation processes. Besides, the process of SEPS extraction significantly enhanced volatile fatty acid (VFA) production during the anaerobic fermentation of residual WAS after SEPS extraction. A maximum VFA yield of 420 ± 14 mg COD/g VS_added was observed in anaerobic fermentation of 10 d, which was 77.2 ± 0.1 % higher than that from raw sludge. Mechanism analysis revealed that SEPS extraction not only improved WAS disintegration and solubilization but also reduced the relative activity of methanogens during anaerobic fermentation. Moreover, SEPS extraction shifted the microbial population during anaerobic fermentation in the direction towards hydrolysis and acidification such as Fermentimonas sp. and Soehngenia sp. This study proposed a novel strategy based on SEPS extraction and VFA production for sludge treatment, offering potential benefits for resource recovery and improved process efficiency.

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处理废弃活性污泥的新策略：回收细胞外结构性聚合物质和发酵产生挥发性脂肪酸

细胞外结构性高分子物质（SEPS）是一种宝贵的生物聚合物，可从废弃活性污泥（WAS）中提取。然而，萃取率通常较低，有关 SEPS 特性的详细信息以及 SEPS 萃取后污泥的适当处理方法仍然有限。本研究旨在优化加热-NaCO萃取工艺的条件，以提高从 WAS 中提取 SEPS 的产量。随后，对 SEPS 进行了表征，并首次利用蛋白质组学揭示了其蛋白质组成。在最佳条件下，即温度为 90 °C、加热时间为 60 分钟、Na 用量为 8.0 mmol/g VS、沉淀所需的 pH 值为 4.0 时，SEPS 的最高产量为 209 mg g 挥发性固体（VS），与文献报道的好氧颗粒污泥的产量相当。蛋白质组学分析表明，SEPS 中的蛋白质主要来自参与固氮和有机物降解的微生物，包括它们的胞内和膜相关区域。这些蛋白质表现出多种催化活性，并在聚集过程中发挥了关键作用。此外，在对 SEPS 提取后的残留 WAS 进行厌氧发酵时，SEPS 提取过程显著提高了挥发性脂肪酸（VFA）的产量。厌氧发酵 10 d 后，挥发性脂肪酸产量最高达 420 ± 14 mg COD/g VS，比原污泥的产量高 77.2 ± 0.1 %。机理分析表明，SEPS 萃取不仅提高了 WAS 的分解和增溶能力，还降低了厌氧发酵过程中甲烷菌的相对活性。此外，SEPS 萃取还使厌氧发酵过程中的微生物种群向水解和酸化方向转移，如 sp.和 sp.。这项研究提出了一种基于 SEPS 提取和 VFA 生产的污泥处理新策略，为资源回收和提高工艺效率提供了潜在的益处。

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来源期刊

Water Research 环境科学-工程：环境

CiteScore

20.80

自引率

9.40%

发文量

1307

审稿时长

38 days

期刊介绍： Water Research, along with its open access companion journal Water Research X, serves as a platform for publishing original research papers covering various aspects of the science and technology related to the anthropogenic water cycle, water quality, and its management worldwide. The audience targeted by the journal comprises biologists, chemical engineers, chemists, civil engineers, environmental engineers, limnologists, and microbiologists. The scope of the journal include: •Treatment processes for water and wastewaters (municipal, agricultural, industrial, and on-site treatment), including resource recovery and residuals management; •Urban hydrology including sewer systems, stormwater management, and green infrastructure; •Drinking water treatment and distribution; •Potable and non-potable water reuse; •Sanitation, public health, and risk assessment; •Anaerobic digestion, solid and hazardous waste management, including source characterization and the effects and control of leachates and gaseous emissions; •Contaminants (chemical, microbial, anthropogenic particles such as nanoparticles or microplastics) and related water quality sensing, monitoring, fate, and assessment; •Anthropogenic impacts on inland, tidal, coastal and urban waters, focusing on surface and ground waters, and point and non-point sources of pollution; •Environmental restoration, linked to surface water, groundwater and groundwater remediation; •Analysis of the interfaces between sediments and water, and between water and atmosphere, focusing specifically on anthropogenic impacts; •Mathematical modelling, systems analysis, machine learning, and beneficial use of big data related to the anthropogenic water cycle; •Socio-economic, policy, and regulations studies.