生物炭对红壤区林地土壤性质及细菌群落的影响

doi:10.13287/j.1001-9332.202509.020

摘要/Abstract

摘要： 农林废弃物数量丰富且易于收集,是制备生物炭的理想原料。本研究以红壤区林地土壤为对象,利用桉树树枝、樟树树枝及番石榴果枝制备生物炭,设置4个添加量:0(CK)、0.5%(w/w)、2%和4%,通过室内短期培养试验(56 d),探究添加生物炭后土壤理化性质的动态变化,并结合高通量测序分析细菌群落多样性,以揭示生物炭-土壤-微生物互作机制。结果表明: 1)与CK相比,生物炭处理的土壤pH值提高了0.25～1.69;有机碳、有效磷、速效钾和硝态氮含量分别显著提高了19.2%～323.5%、31.8%～69.8%、10.3%～448.7%和46.9%～118.2%。2)与CK相比,添加4%番石榴生物炭的土壤脲酶活性显著提升108.5%,添加4%桉树生物炭、4%樟树生物炭的土壤蔗糖酶和纤维素酶活性分别显著提升26.8%～43.0%和8.6%～8.9%。3)高通量测序结果显示,与CK相比,添加1%番石榴生物炭、1%樟树生物炭和4%桉树生物炭提升了土壤细菌群落多样性,Shannon指数、Simpson指数和Chao1指数均显著提高。土壤中优势细菌门类主要为变形菌门、黏菌门,其相对丰度占比分别为23.1%～31.4%和11.7%～23.3%。冗余分析表明,速效钾、pH值、碱解氮、有机碳及蔗糖酶是影响细菌群落的主要环境因子,生物炭通过改变土壤理化特性间接影响土壤细菌群落组成和丰度。综上,3种生物炭可有效改善红壤区林地土壤质量并提升细菌群落多样性,其中4%添加量效果最佳。

关键词: 林地土壤, 生物炭, 土壤理化性质, 细菌多样性, 土壤酶活性

Abstract: Agricultural and forestry residues, being abundant and easily collectible, serve as ideal feedstocks for biochar production. We established four biochar application rates: 0% (CK), 0.5%, 2%, and 4%, (w/w), to conduct a short-term indoor incubation experiment (lasting 56 days) with red soil and investigated the changes in soil physicochemical properties after biochar addition. Biochar was produced with eucalyptus branches, camphor tree branches, and guava fruit branches. By using high-throughput sequencing, we analyzed the diversity of bacterial communities. The results showed that: 1) Compared with CK, biochar amendment increased soil pH by 0.25-1.69 units and significantly enhanced organic carbon (19.2%-323.5%), available phosphorus (31.8%-69.8%), available potassium (10.3%-448.7%), and nitrate (46.9%-118.2%) contents. 2) Urease activity was increased by 108.5% with 4% guava biochar, while sucrase and cellulase activities was enhanced by 26.8%-43.0% and 8.6%-8.9%, respectively, under 4% eucalyptus or camphor biochar. 3) High-throughput sequencing revealed that 1% guava biochar, 1% camphor biochar, and 4% eucalyptus biochar elevated bacterial diversity, as indicated by the significant increases in Shannon, Simpson, and Chao1 indices. Dominant phyla included Proteobacteria (23.1%-31.4%) and Acidobacteria (11.7%-23.3%). Redundancy analysis identified available potassium, pH, available nitrogen, organic carbon, and sucrase as key environmental drivers, demonstrating that biochar indirectly modulates bacterial composition through physicochemical modifications. In conclusion, all three types of biochar effectively improved soil quality and bacterial diversity of red soil, with the 4% application rate achieved the best effect.

Key words: forest soil, biochar, soil physicochemical properties, bacterial diversity, soil enzyme activity

黎浩文, 梁永鑫, 黄英梅, 梁春梅, 张俊涛, 刘可星. 生物炭对红壤区林地土壤性质及细菌群落的影响[J]. 应用生态学报, 2025, 36(9): 2771-2781.

LI Haowen, LIANG Yongxin, HUANG Yingmei, LIANG Chunmei, ZHANG Juntao, LIU Kexing. Effects of biochar on soil properties and bacterial community in forest of red soil region[J]. Chinese Journal of Applied Ecology, 2025, 36(9): 2771-2781.

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