长期有机无机肥配施对团聚体有机碳分布与矿化影响及其作用机制

doi:10.11924/j.issn.1000-6850.casb2025-0812

摘要/Abstract

摘要：

为探究土壤团聚体有机碳分布和有机碳矿化，阐明长期不同有机无机肥配施对土壤有机碳矿化的影响以及团聚体对有机碳矿化的作用机制，以连续36年（1988—2023年）长期不同有机无机肥配施的南方农田红壤为研究对象，分别采集NPK、NPK+绿肥、NPK+厩肥处理的0~10、10~20 cm深度土壤，测定土壤及不同粒径团聚体中有机碳(SOC)含量、土壤呼吸CO₂释放量和土壤理化性质等指标。结果表明，长期有机无机肥配施条件下，在0~20 cm的土层中：（1）与NPK处理相比较，有机无机配施提高了SOC含量，NPK+厩肥处理的SOC含量整体高于NPK+绿肥处理，NPK+厩肥处理相较于NPK处理显著提高了SOC含量，增幅为77.39%，并且有机碳主要分布于NPK+厩肥处理中粒径小于0.053 mm的微团聚体中，占比为86.43%。（2）NPK处理下的CO₂量和CO₂/SOC比值显著大于NPK+厩肥和NPK+绿肥处理，说明有机无机肥配施使得土壤矿化能力显著降低，呼吸作用减弱，CO₂释放量变低。（3）土壤SOC含量与TN、TP含量呈显著正相关(P<0.01)，CO₂与小团聚体碳含量之间显著负相关(P<0.05)，说明粒径0.053~0.25 mm的团聚体能更好地保护有机碳，增强对有机碳的物理保护作用和固持能力，使有机碳不易被微生物分解，长期施肥主要通过影响土壤中氮、磷的含量，从而影响有机质在团聚体中的含量和分布以及土壤的矿化能力。综上，连续36年有机无机配施通过增加团聚体SOC含量和土壤中氮、磷的含量，减少SOC矿化。研究结果可为南方农田红壤有机质提升与稳定以及优化施肥管理模式提供理论依据。

关键词: 土壤有机碳, 长期定位试验, 有机无机肥配施, 团聚体, 有机碳矿化

Abstract:

To explore the distribution and mineralization of organic carbon in soil aggregates, this study clarified the effects of long-term application of different organic and inorganic fertilizers on soil organic carbon mineralization and the mechanism of aggregates in this process. This study used the red soil of southern farmland treated with different organic-inorganic fertilizers for 36 consecutive years (1988 to 2023) as the research object. Soil samples were collected at depths of 0-10 cm and 10-20 cm respectively under NPK, NPK+ green manure, and NPK+ barnyard manure treatments. The contents of organic carbon (SOC), the release of CO₂ from soil respiration, soil physicochemical properties and other indicators were determined in the soil and aggregates of different particle sizes. The results showed that under long-term combined application of organic and inorganic fertilizers, in the soil layer of 0-20 cm, (1) compared with the NPK treatment, the combined application of organic and inorganic fertilizers increased the SOC content, with the NPK+ barnyard manure treatment significantly increasing the SOC content by 77.39%. The SOC content of the NPK+ barnyard manure treatment was overall higher than that of the NPK+ green manure treatment. Moreover, organic carbon was mainly distributed in the micro-aggregates with a particle size of less than 0.053 mm in the NPK+ barnyard manure treatment, accounting for 86.43%. (2) The amount of CO₂ and the CO₂/SOC ratio under NPK treatment were significantly higher than those under NPK+ barnyard manure and NPK+ green manure treatments, indicating that the combined application of organic and inorganic fertilizers significantly reduced soil mineralization capacity, weakened respiration, and decreased the release of CO₂. (3) The content of SOC in soil was significantly positively correlated with the contents of TN and TP (P<0.01), and negatively correlated with the contents of CO₂ and fPOC (P<0.05). This indicated that aggregates with a particle size of 0.053-0.25 mm could better protect organic carbon, enhance the physical protective effect and retention capacity for organic carbon, and prevent organic carbon from being decomposed by microorganisms. It could be concluded that long-term fertilization mainly affects the content and distribution of organic matter in aggregates and the mineralization capacity of the soil by influencing the content of nitrogen and phosphorus in the soil. In summary, the combined application of organic and inorganic fertilizers for 36 consecutive years provided a theoretical basis for enhancing and stabilizing soil organic matter in southern farmland red soils and for optimizing the fertilization management model, by increasing SOC content in aggregates, increasing soil nitrogen and phosphorus content, and reducing SOC mineralization.

Key words: soil organic carbon, long-term location test, combined application of organic and inorganic fertilizers, aggregate, organic carbon mineralization

中图分类号:

S152.4

鲍雨薇, 黄婷婷, 陈恒羽, 潘广莎, 孙婷婷. 长期有机无机肥配施对团聚体有机碳分布与矿化影响及其作用机制[J]. 中国农学通报, 2026, 42(10): 124-131.

BAO Yuwei, HUANG Tingting, CHEN Hengyu, PAN Guangsha, SUN Tingting. Influence and Mechanism of Long-term Combined Application of Organic and Inorganic Fertilizers on Organic Carbon Distribution and Mineralization in Aggregates[J]. Chinese Agricultural Science Bulletin, 2026, 42(10): 124-131.

图/表 4

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处理	土层/cm	最大田间持水量/%	pH	SOC/(g/kg)	TN/(g/kg)	NO₃^--N/(mg/kg)	TP/(g/kg)	AP/(mg/kg)
NPK	0~10	0.16±0.00a	5.65±0.02a	6.82±0.33b	0.66±0.01c	10.90±2.20b	0.63±0.05b	38.28±9.33b
NPK+厩肥		0.16±0.01a	5.72±0.12a	11.68±1.6a	1.04±0.02a	27.34±0.50a	2.13±0.07a	217.28±45.83a
NPK+绿肥		0.15±0.01a	5.30±0.03b	8.65±1.03b	0.79±0.01b	14.90±4.26b	0.61±0.03b	28.83±8.39b
NPK	10~20	0.19±0.01a	4.75±0.05c	4.76±0.11b	0.52±0.02b	12.09±1.68a	0.39±0.01a	4.52±1.18b
NPK+厩肥		0.17±0.01a	5.33±0.04a	4.00±0.11c	0.47±0.01a	11.39±1.73a	0.56±0.04a	197.61±41.32a
NPK+绿肥		0.18±0.01a	5.05±0.06b	6.60±0.11a	0.63±0.01c	12.85±3.64a	0.56±0.15a	9.23±2.06b

处理	土层/cm	最大田间持水量/%	pH	SOC/(g/kg)	TN/(g/kg)	NO₃^--N/(mg/kg)	TP/(g/kg)	AP/(mg/kg)
NPK	0~10	0.16±0.00a	5.65±0.02a	6.82±0.33b	0.66±0.01c	10.90±2.20b	0.63±0.05b	38.28±9.33b
NPK+厩肥		0.16±0.01a	5.72±0.12a	11.68±1.6a	1.04±0.02a	27.34±0.50a	2.13±0.07a	217.28±45.83a
NPK+绿肥		0.15±0.01a	5.30±0.03b	8.65±1.03b	0.79±0.01b	14.90±4.26b	0.61±0.03b	28.83±8.39b
NPK	10~20	0.19±0.01a	4.75±0.05c	4.76±0.11b	0.52±0.02b	12.09±1.68a	0.39±0.01a	4.52±1.18b
NPK+厩肥		0.17±0.01a	5.33±0.04a	4.00±0.11c	0.47±0.01a	11.39±1.73a	0.56±0.04a	197.61±41.32a
NPK+绿肥		0.18±0.01a	5.05±0.06b	6.60±0.11a	0.63±0.01c	12.85±3.64a	0.56±0.15a	9.23±2.06b