Integrating dark fermentation and electrohydrogenesis for enhanced biohydrogen production from food waste

IF 4.1 3区材料科学 Q2 CHEMISTRY, PHYSICAL

Sustainable Energy & Fuels Pub Date : 2025-08-29 DOI:10.1039/D5SE00571J

Anam Jalil, Hikmatullah Ahmadi, Fabrice Ndayisenga, Sohail Khan, Atif Ahmad, Xiangyang Wang and Zhisheng Yu

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Abstract

Biohydrogen production from food waste offers a sustainable and carbon-neutral alternative to fossil fuels. However, its large-scale application is limited by the rapid hydrolysis of biodegradable organics, resulting in the accumulation of inhibitory byproducts such as ammonia and volatile fatty acids (VFAs), especially lactic acid. These compounds suppress hydrogen-producing bacteria and reduce system efficiency. Integrating dark fermentation (DF) with microbial electrolysis cells (MECs) has emerged as a promising approach to overcome these limitations by converting residual organics into additional hydrogen via electrohydrogenesis. Optimization of operational parameters such as pH, hydraulic retention time (HRT), and organic loading rate (OLR) further enhances hydrogen yield by minimizing VFA accumulation and improving system stability. Integrated DF–MEC systems have achieved hydrogen yields of up to 1608.6 ± 266.2 mL H₂ per g COD consumed and COD removal efficiencies of 78.5 ± 5.7%. Heat pretreatment and the use of genetically engineered microbial strains have been shown to further enhance hydrogen production. Engineered strains have delivered hydrogen yields ranging from 0.47 to 1.88 mol H₂ per mol glucose. MEC integration has also demonstrated a 30–40% increase in hydrogen production compared to standalone DF systems. The digestate from lactate-driven DF, enriched with VFAs such as acetate and lactate, provides an excellent substrate for MECs, thereby enhancing electrohydrogenesis. Despite high initial capital costs, the long-term benefits, such as waste valorization, greenhouse gas reduction, and renewable energy recovery, make the DF–MEC system a viable and scalable solution for sustainable hydrogen production from food waste.

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结合暗发酵和电制氢，提高食物垃圾生物制氢的效率

从食物垃圾中生产生物氢为化石燃料提供了一种可持续的、碳中和的替代品。然而，它的大规模应用受到生物可降解有机物快速水解的限制，导致氨和挥发性脂肪酸（VFAs），特别是乳酸等抑制副产物的积累。这些化合物抑制产氢细菌，降低系统效率。将暗发酵（DF）与微生物电解细胞（MECs）相结合是克服这些限制的一种很有前途的方法，通过电氢发生将残余有机物转化为额外的氢。通过优化pH、水力停留时间（HRT）和有机负载率（OLR）等操作参数，最大限度地减少VFA积累，提高系统稳定性，进一步提高氢气产量。集成DF-MEC系统的产氢率高达每g COD消耗1608.6±266.2 mL H2， COD去除效率为78.5±5.7%。热预处理和基因工程微生物菌株的使用已被证明可以进一步提高氢气的产量。工程菌株的氢气产量从每摩尔葡萄糖0.47到1.88摩尔氢气不等。MEC集成也表明，与独立的DF系统相比，氢气产量增加了30-40%。乳酸驱动DF的消化液富含乙酸和乳酸等VFAs，为mec提供了良好的底物，从而增强了电氢作用。尽管初始投资成本很高，但其长期效益，如废物增值、温室气体减排和可再生能源回收，使DF-MEC系统成为一种可行的、可扩展的解决方案，用于从食物垃圾中可持续制氢。

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来源期刊

Sustainable Energy & Fuels Energy-Energy Engineering and Power Technology

CiteScore

10.00

自引率

3.60%

发文量

394

期刊介绍： Sustainable Energy & Fuels will publish research that contributes to the development of sustainable energy technologies with a particular emphasis on new and next-generation technologies.