Constructing bimetal, alloy, and compound-modified nitrogen-doped biomass-derived carbon from coconut shell as accelerants for boosting methane production in bioenergy system

Energy Materials Pub Date : 2024-01-16 DOI:10.20517/energymater.2023.62

Teng Ke, Sining Yun, Kaijun Wang, Tian Xing, Jiaoe Dang, Yongwei Zhang, Menglong Sun, Jinhang An, Lijianan Liu, Jiayu Liu

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Abstract

Accelerants can enhance methane production in biomass energy systems. Single-component accelerants cannot satisfy the demands of anaerobic co-digestion (AcoD) to maximize overall performance. In this work, nitrogen-doped bio-based carbon derived from coconut shells, containing bimetallic Ni/Fe nanoparticles, FeNi3 alloys, and compounds (Fe2O3, FeN, and Fe3O4), was constructed as hybrid accelerants (Ni-N-C, Fe-N-C, and Fe/Ni-N-C) to boost CH4 production and CO2 reduction. The cumulative biogas yield (553.65, 509.65, and 587.76 mL/g volatile solids), methane content (63.58%, 57.90%, and 67.39%), and total chemical oxygen demand degradation rate (60.15%, 54.92%, and 65.38%) of AcoD with Ni-N-C (2.625 g/L), Fe-N-C (3.500 g/L), and Fe/Ni-N-C (2.625 g/L) were higher than control (346.32 mL/g volatile solids, 40.13%, and 32.03%), respectively. These digestates with Ni-N-C, Fe-N-C, and Fe/Ni-N-C showed excellent stability (mass loss: 22.97%-32.75%) and total nutrient content (4.43%-4.61%). Based on the synergistic effects of the different components of the hybrid accelerant, an understanding of the enhanced methanogenesis of AcoD was illustrated.

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利用椰壳构建双金属、合金和复合改性掺氮生物质衍生碳，作为促进生物能源系统甲烷生产的助燃剂

促进剂可以提高生物质能源系统中的甲烷产量。单组分促进剂无法满足厌氧协同消化（AcoD）的要求，无法最大限度地提高整体性能。在这项工作中，从椰子壳中提取的掺氮生物基碳，含有双金属镍/铁纳米颗粒、FeNi3 合金和化合物（Fe2O3、FeN 和 Fe3O4），被构建成混合促进剂（Ni-N-C、Fe-N-C 和 Fe/Ni-N-C），以提高甲烷产量和二氧化碳减排量。累积沼气产量（553.65、509.65 和 587.76 毫升/克挥发性固体）、甲烷含量（63.58%、57.90% 和 67.39%）和总化学需氧量降解率（60.15%、54.含 Ni-N-C (2.625 g/L)、Fe-N-C (3.500 g/L) 和 Fe/Ni-N-C (2.625 g/L) 的 AcoD 的甲烷含量、总化学需氧量降解率（60.15%、54.92% 和 65.38%）分别高于对照组（346.32 mL/g 挥发性固体、40.13% 和 32.03%）。含有 Ni-N-C、Fe-N-C 和 Fe/Ni-N-C 的沼渣表现出良好的稳定性（质量损失：22.97%-32.75%）和总养分含量（4.43%-4.61%）。基于混合促进剂中不同成分的协同效应，我们对 AcoD 的甲烷生成能力增强有了一定的了解。

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