不同改土措施对白浆土耕作特性的影响

doi:10.13287/j.1001-9332.202512.019

摘要/Abstract

摘要： 针对低产白浆土因物理结构障碍导致的耕作特性较差,不利于机械耕作作业的问题,本研究通过室内模拟试验,以无掺混为对照,设置耕层混拌(TLM,白浆层土按10%～50%掺入表土中)、心土混层(SM,淀积层土按10%～50%掺入白浆层土中)及心土培肥(SF,有机肥、秸秆、生物炭添加梯度2%～10%)3类处理,分析不同改土措施对白浆土可塑性(采用液限、塑限、塑性指数指示)、胀缩性(采用缩限指示)及适宜耕作期(采用收缩指数指示)的差异化调控机制。结果表明: 与对照相比,TLM提升了土壤均质化程度,但显著增强了土壤可塑性,缩短土壤适宜耕作期,导致耕作特性劣化。SM通过提高黏粒含量和优化黏沙比提升了白浆土耕作性能,使适宜耕作期显著延长。SF依托有机质、比表面积、最大吸湿水和有机碳的协同增效,对白浆土耕作特性的改良效果显著优于TLM和SM处理,其中,有机肥通过提升土壤持水能力(塑限增幅为37.5%～58.1%)优化土壤适耕性;秸秆对土壤膨缩性的调控效果最显著(缩限降幅最高达41.1%),秸秆添加量为6%时效果最佳;生物炭则通加多级孔隙结构优化土壤适耕性,在添加量为10%时,液限和塑限分别提升了7.3%、14.9%,塑性指数下降了7.6%,收缩指数增加了12.6%,表明3种培肥物料均可不同程度改良低产白浆土耕作特性。本研究可为白浆土障碍修复与可持续耕作体系构建提供理论支撑。

关键词: 耕层混拌, 心土混层, 心土培肥, 白浆土, 耕作特性

Abstract: The poor tillage properties in low-yielding albic soil caused by physical structural obstacles are unfavorable for mechanical tillage operations. To address this problem, we conducted indoor simulation experiments with three types of treatments: tillage layer mixing (TLM, where 10%-50% of the albic soil was incorporated into the surface soil), subsoil mixing (SM, where 10%-50% of the illuvial soil was incorporated into the albic soil), and subsoil fertilization (SF, with gradients of 2%-10% organic fertilizer, straw, and biochar addition, respectively). We analyzed the differential regulatory mechanisms of various soil improvement measures on the plasticity (indicated by liquid limit, plastic limit, and plasticity index), swelling-shrinkage behavior (indicated by shrinkage limit), and optimal tillage period (indicated by shrinkage index) of albic soil. Results showed that TLM improved soil homogeneity and plasticity, shortened the optimal tillage period, and degraded tillage characteristics. SM improved the tillage performance of albic soil by increasing clay content and optimizing the sand-clay ratio, which together extended the optimal tillage period. SF, leveraging the synergistic effects of organic matter, specific surface area, maximum hygroscopic water, and organic carbon, demonstrated superior improvement effects on tillage characteristics compared to TLM and SM. Among these, organic fertilizer enhanced soil water retention capacity (plastic limit increased by 37.5%-58.1%), optimizing soil tillage characteristics. Straw exhibited the most significant regulatory effect on soil swelling-shrinkage behavior (shrinkage limit decreased by up to 41.1%), with the optimal effect achieved at a 6% straw addition. Biochar improved soil tillability by optimizing the hierarchical pore structure, where a 10% addition increased the liquid limit and plastic limit by 7.3% and 14.9%, respectively, while reducing the plasticity index by 7.6% and increasing the shrinkage index by 12.6%. These findings indicated that all three soil fertilization materials could improve the tillage characteristics of low-yielding albic soil. This study would provide theoretical support for the remediation of albic soil barriers and the construction of sustainable tillage systems.

Key words: tillage layer mixing, subsoil mixing, subsoil fertilization, albic soil, tillage characteristics

陈爱慧, 张海滨, 王秋菊, 于晓波, 谭增鑫, 周魏岩, 任洪忱, 闫景凤. 不同改土措施对白浆土耕作特性的影响[J]. 应用生态学报, 2025, 36(12): 3699-3708.

CHEN Aihui, ZHANG Hai-bin, WANG Qiuju, YU Xiaobo, TAN Zengxin, ZHOU Weiyan, REN Hongchen, YAN Jingfeng. Effects of different improvement measures on tillage characteristics of albic soil[J]. Chinese Journal of Applied Ecology, 2025, 36(12): 3699-3708.

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