水热碳化
生物炭
修正案
土壤碳
化学
碳纤维
稻草
生物量(生态学)
肥料
环境化学
固碳
土壤有机质
土壤改良剂
木质素
有机质
原材料
微观世界
总有机碳
土壤水分
热解
土壤化学
溶解有机碳
制浆造纸工业
农学
鸡粪
营养物
腐殖质
木炭
Ultisol公司
作者
Liyang Sun,H. Wei,Wei Sun,Pingping Ye,Yue Deng,Xiangtian Meng,Na Luo,Zongsheng Zhang,Xiaoxuan Su,Ran Xiao
出处
期刊:Biochar
[Springer Nature]
日期:2026-03-04
卷期号:8 (1)
标识
DOI:10.1007/s42773-025-00547-y
摘要
Abstract Enhancing soil organic carbon (SOC) and aggregate stability is pivotal for maintaining soil health and ensuring agricultural sustainability. However, conventional organic amendments often exhibit suboptimal efficiency in achieving these goals. Hydrochar, synthesized via hydrothermal carbonization (HTC), offers a promising solution by integrating labile and recalcitrant carbon fractions to synergistically address these challenges. However, its mechanisms of action remain not fully understood. In the present study, a microcosmic incubation experiment was conducted to evaluate the short-term impacts of hydrochar on SOC sequestration and soil aggregation in comparison with biochar and straw in a purple soil ( Entisol ). Hydrochars derived from maize straw (SH), pig manure (PH), and Zanthoxylum stalks (HH) were also compared to assess feedstock-driven variability. The results demonstrated the superior performance of hydrochars, particularly those derived from Zanthoxylum stalks, which significantly increased the mean weight diameter (MWD) by 70–100% and SOC content by 143–149%, outperforming biochar and straw. Specifically, hydrochar-originated carbon persisted primarily as particulate organic matter (POM) and accumulated in macro-aggregate, while shifts in microbial communities contributed to SOC stabilization. In comparison, soil aggregation was driven by labile carbon fractions (e.g., dissolved organic carbon, DOC) and soil microorganisms, specifically Actinobacteria and Ascomycota . Feedstock properties, such as the C/N ratio and lignin content, modulated the effectiveness of hydrochar as a soil amendment. Notably, stalk-derived hydrochar exhibited superior carbon retention (12% total carbon loss vs. 30–44% for other amendments) and aggregate stability due to its recalcitrant lignin structure. Nutrient content and ratio further influenced these outcomes, with manure-derived hydrochar promoting microbial biomass carbon (845 mg kg −1 vs. 350 mg kg −1 in control), while stalk-derived hydrochar was more effective at optimizing carbon sequestration. These findings highlighted the dual role of hydrochar in enhancing soil structure and SOC sequestration, with feedstock selection critically determining functional priorities. Such insights could provide valuable guidance for tailoring hydrochar production and application to improve agricultural sustainability through soil quality improvement. Graphic Abstract
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