Insights into hydrochar’s physicochemical properties evolution and nitrogen migration mechanism during co-hydrothermal carbonization of microalgae and corn stalk with FeCl3/NH4Cl/melamine addition

IF 9.7 1区环境科学与生态学 Q1 AGRICULTURAL ENGINEERING

Bioresource Technology Pub Date : 2025-05-01 DOI:10.1016/j.biortech.2025.132612

Yang Peng , Xianqing Zhu , Qian Shen , Yun Huang , Ao Xia , Jingmiao Zhang , Xun Zhu , Qiang Liao

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Abstract

Co-hydrothermal carbonization (co-HTC) of microalgae and lignocellulosic biomass can boost co-hydrochar yield and nitrogen retention rate, but the co-hydrochar still suffers from low nitrogen content and porosity. Accordingly, in this study, FeCl₃, NH₄Cl and melamine were employed as additives to intensify the co-HTC process of microalgae (CP) and corn stalk (CS), and their impacts on the co-hydrochar yield, physicochemical properties and nitrogen transformation pathways were firstly investigated comprehensively. The results indicated that adding FeCl₃ increased co-hydrochar’s specific surface area, but the oxidation power of Fe³⁺ facilitated nitrogen into the aqueous-phase products, leading to the nitrogen distribution in aqueous-phase products reaching up to 83.51 %. Melamine incorporation increased the nitrogen content of co-hydrochar (6.95 %) and oil-phase products, while reduced co-hydrochar’s porosity. NH₄Cl was the most effective additive for nitrogen-doped hydrochar production, simultaneously increasing the yield (40.24 %), nitrogen content (8.93 %) and specific surface area (9.12 m² g⁻¹) of co-hydrochar. The nitrogen transformation mechanism during NH₄Cl-assisted co-HTC process could be divided into two stages. At the first stage (200 ℃–240 ℃), the NH₄⁺ in NH₄Cl could react with hydrolysis intermediates (Maillard and Mannich reactions) to generate heterocyclic nitrogen compounds entering the oil-phase, which would further react with the oxygen-containing functional groups to facilitate the nitrogen enrichment in the co-hydrochar. At the second stage (240 ℃–280 ℃), a portion of hydrochar would undergo secondary degradation and formed water-soluble nitrogen-rich small molecules, which were transferred to the aqueous-phase products again. This study demonstrated the high feasibility of additive-assisted co-HTC for producing high-quality nitrogen-rich carbon materials.

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微藻与玉米秸秆在FeCl3/NH4Cl/三聚氰胺共水热炭化过程中烃类物化性质演变及氮迁移机制研究

微藻和木质纤维素生物质的共水热碳化（co-HTC）可以提高共氢炭的产率和氮潴留率，但共氢炭仍存在低氮含量和孔隙率的问题。因此，本研究首次以FeCl3、NH4Cl和三聚氰胺作为添加剂强化微藻（CP）和玉米秸秆（CS）的共htc过程，全面考察了它们对共烃产率、理化性质和氮转化途径的影响。结果表明，FeCl3的加入增加了共氢的比表面积，但Fe3+的氧化能力促进了氮进入水相产物，导致水相产物中氮的分布高达83.51%。三聚氰胺的掺入提高了共烃和油相产物的含氮量（6.95%），降低了共烃的孔隙度。NH4Cl是最有效的氮掺杂氢炭添加剂，同时提高了共氢炭的产率（40.24%）、氮含量（8.93%）和比表面积（9.12 m2 g−1）。nh4cl辅助co-HTC过程中的氮转化机理可分为两个阶段。在第一阶段（200℃-240℃），NH4Cl中的NH4+与水解中间体（Maillard和Mannich反应）反应生成进入油相的杂环氮化合物，杂环氮化合物会进一步与含氧官能团反应，促进共烃中的氮富集。在第二阶段（240℃-280℃），一部分烃类发生二次降解，形成水溶性富氮小分子，再次转移到水相产物中。本研究证明了添加剂辅助co-HTC制备高质量富氮碳材料的可行性。

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来源期刊

Bioresource Technology 工程技术-能源与燃料

CiteScore

20.80

自引率

19.30%

发文量

2013

审稿时长

12 days

期刊介绍： Bioresource Technology publishes original articles, review articles, case studies, and short communications covering the fundamentals, applications, and management of bioresource technology. The journal seeks to advance and disseminate knowledge across various areas related to biomass, biological waste treatment, bioenergy, biotransformations, bioresource systems analysis, and associated conversion or production technologies. Topics include: • Biofuels: liquid and gaseous biofuels production, modeling and economics • Bioprocesses and bioproducts: biocatalysis and fermentations • Biomass and feedstocks utilization: bioconversion of agro-industrial residues • Environmental protection: biological waste treatment • Thermochemical conversion of biomass: combustion, pyrolysis, gasification, catalysis.