石灰和生物炭对酸化土壤pH与微生物性质影响的Meta分析

doi:10.13287/j.1001-9332.202601.018

摘要/Abstract

摘要： 农田土壤酸化问题日益凸显,已成为危害土壤健康的重要因素,施用碱性物料是缓解土壤酸化简单可行的方式,但其对土壤微生物特性的影响尚不明确。本研究通过收集1980—2024年间发表的碱性物料(石灰和生物炭)对酸化土壤pH、微生物生物量碳和微生物多样性影响的文献进行Meta分析,以明确碱性物料的降酸效应及对微生物性质的影响。结果表明: 施用石灰和生物炭均能显著提升土壤pH(9.1%和4.4%),其提升幅度随施用量增加而增大;在施用后0.25年内提升效果最好,分别为19.7%和9.4%;高温(>16 ℃)、高降雨(>1200 mm)及强酸性土壤(pH≤4.5)中碱性物料的改良效果最好。施用石灰和生物炭后土壤微生物生物量碳增加约81.6%和18.4%,提升效果主要体现在施用后1～2年内;石灰较高施用量(3～6 t·hm^-2·a^-1)提升效果最佳,而生物炭低施用量(≤1.5 t·hm^-2·a^-1)提升效果更优。施用碱性物料后微生物多样性整体增加2.5%,施用生物炭0.25～0.5年提升效果最高,为14.1%,而施用石灰>2年后微生物多样性才显著提升(8.5%);石灰对低温低雨区微生物多样性的提升较高(达6.8%),而生物炭更适用于高温高湿区(提升5.5%)。施用生物炭主要通过调节土壤pH间接影响微生物性质,微生物生物量碳和多样性与土壤pH呈显著正相关;而施用石灰后微生物的变化受施用量、气候因素和初始土壤pH等因素影响。本研究明确了不同碱性物料的降酸效应及对土壤微生物特性的调控机制,为进一步探讨酸化土壤改良过程中物理、化学与生物耦合的恢复机制提供了研究基础。

关键词: 石灰, 生物炭, 土壤pH, 土壤微生物生物量碳, 微生物多样性

Abstract: Soil acidification in agricultural lands has become an increasingly prominent issue, posing a serious threat to soil health. Alkaline amendments is a feasible approach to mitigate acidification, yet their effects on soil microbial properties remain unclear. We conducted a meta-analysis with literature published during 1980 to 2024, to examine the impacts of alkaline materials (lime and biochar) on soil pH, microbial biomass carbon, and microbial diversity in acidified soils. Results showed that both lime and biochar significantly increased soil pH (by 9.1% and 4.4%, respectively), with greater improvements at higher application rates. The strongest effects occurred within 0.25 years after application (19.7% for lime and 9.4% for biochar). Alkaline amendments were the most effective under high temperature (>16 ℃), high rainfall (>1200 mm), and strongly acidic soils (pH≤4.5). Lime and biochar increased microbial biomass carbon by 81.6% and 18.4%, respectively, with the greatest effects observed within 1-2 years. Higher lime application rates (3-6 t·hm^-2·a^-1) produced the strongest improvements, whereas biochar was more effective at lower rates (≤1.5 t·hm^-2·a^-1). Overall, microbial diversity increased by 2.5% following amendment application. Biochar enhanced microbial diversity most strongly within 0.25-0.5 years (14.1%), while lime required more than two years to achieve significant improvement (8.5%). Lime was more effective in low-temperature, low-rainfall regions (up to 6.8%), whereas biochar was better suited to high-temperature, high-rainfall regions (5.5%). Biochar influenced microbial properties indirectly by regulating soil pH, with microbial biomass and diversity showing significant positive correlations with soil pH. In contrast, lime-induced changes in microbial properties were strongly affected by application rate, climatic condition, and initial soil pH. This study clarified the acid-neutralizing effects and soil microbial regulation mechanisms of different alkaline amendments, providing a foundation for further exploration of the coupled physical, chemical, and biological restoration processes in the amelioration of acidified soils.

Key words: lime, biochar, soil pH, soil microbial biomass carbon, microbial diversity

曾琪, 李丹丹, 蔡泽江, 孙楠, 徐明岗. 石灰和生物炭对酸化土壤pH与微生物性质影响的Meta分析[J]. 应用生态学报, 2026, 37(1): 103-114.

ZENG Qi, LI Dandan, CAI Zejiang, SUN Nan, XU Minggang. Liming and biochar effects on soil pH and microbial properties in acidified soils: A meta-analysis[J]. Chinese Journal of Applied Ecology, 2026, 37(1): 103-114.

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