Effects of Soil Properties and Yield of Double-Cropping Rice in Southern China under Conservation Tillage Mode

doi:10.16258/j.cnki.1674-5906.2025.04.003

Ecology and Environment ›› 2025, Vol. 34 ›› Issue (4): 521-533.DOI: 10.16258/j.cnki.1674-5906.2025.04.003

• Research Article【Ecology】 • Previous Articles Next Articles

Effects of Soil Properties and Yield of Double-Cropping Rice in Southern China under Conservation Tillage Mode

DU Minghui¹^,²^,³(), LI Boxin⁴, YU Yingde⁵, TAO Lin¹^,²^,³, FAN Shixian¹^,²^,³, YU Minnan¹^,²^,³, YU Xiaowen⁶, ZOU Shujun¹^,²^,³, HUANG Deyin¹^,²^,³^,^*()

1. Institute of Eco-environmental and Soil Sciences, Guangdong Academy of Sciences, Guangzhou 510650, P. R. China
2. National-Regional Joint Engineering Research Center for Soil Pollution Control and Remediation in South China, Guangzhou 510650, P. R. China
3. Guangdong Key Laboratory of Integrated Agro-environmental Pollution Control and Management, Guangzhou 510650, P. R. China
4. Zhuhai Modern Agricultural Development Center, Zhuhai 519055, P. R. China
5. Zhuhai Jinwan District Agriculture Rural and Water Bureau, Zhuhai 519000, P. R. China
6. Zhuhai Doumen District Agricultural Technology Extension Station, Zhuhai 519199, P. R. China

Received:2024-09-08 Online:2025-04-18 Published:2025-04-24
Contact: HUANG Deyin

保护性耕作对南方双季稻田土壤性质及产量的影响

杜明慧¹^,²^,³(), 李伯欣⁴, 余英德⁵, 陶琳¹^,²^,³, 范世献¹^,²^,³, 余敏男¹^,²^,³, 于晓雯⁶, 邹淑君¹^,²^,³, 黄德银¹^,²^,³^,^*()

1.广东省科学院生态环境与土壤研究所，广东广州 510650
2.华南土壤污染控制与修复国家地方联合工程研究中心，广东广州 510650
3.广东省农业环境综合治理重点实验室，广东广州 510650
4.珠海市现代农业发展中心，广东珠海 519055
5.珠海市金湾区农业农村和水务局，广东珠海 519000
6.珠海市斗门区农业技术推广总站，广东珠海 519199

通讯作者: 黄德银
作者简介:杜明慧（1997年生），女，硕士，研究方向为土壤污染研究防治。E-mail: mhdu@soil.gd.cn
基金资助:
广东省科学院百名青年人才培养专项(2020GDASYL-20200104018);广东省科技计划项目(2023B1212060044)

Abstract

Abstract:

Conservation tillage, which reduces soil disturbance compared to traditional high-intensity tillage methods, is an environmentally friendly and economical approach. In this study, two double-cropping rice-planting areas in Leizhou and Dapu in Guangdong Province were selected for a two-year fixed-site experiment. Using traditional tillage as a control, we examined the effects of no-tillage and reduced-tillage conservation practices on soil structure, soil organic matter, and rice yield in southern double-cropping systems. The results showed that conservation tillage had no significant effect on the soil bulk density or porosity at either location. However, the effect of reduced tillage on soil organic matter and macro-aggregate content varied by region. In Leizhou, reduced tillage generally increased the content of soil organic matter and macroaggregates, with the highest increases reaching 48.8% and 17.4%, respectively. In contrast, in Dapu, organic matter decreased slightly, and macroaggregate content showed no significant change. Rice yield responded significantly to different tillage modes. In both Leizhou and Dapu, double-cropping rice yield was the highest under reduced tillage (p<0.05), with the highest increase reaching 12.7% and no tillage slightly higher than traditional tillage. The reduced tillage mode helps mitigate leaching, surface runoff, and the loss of nitrogen and phosphorus due to heavy rainfall in the southern region, and also reduces soil erosion, thereby increasing rice yield. This study indicates that while short-term conservation tillage (2 a) has no significant impact on soil structure, reduced tillage appears to be a more effective practice for enhancing rice yield in southern double-cropping systems. These findings have practical significance for improving paddy field soil fertility and crop yields under different tillage modes in southern China.

Key words: tillage modes, double-cropping rice, soil structure, soil organic matter, rice yield

摘要： 保护性耕作相比于传统高强度的耕作方式减少了对土壤的扰动，是一种环保且经济的耕作方法。选取广东省雷州和大埔两个双季稻种植区进行2 a的定位试验，以传统耕作为对照，研究免耕、少耕保护性耕作方式对稻田土壤结构、土壤有机质及水稻产量的影响。结果表明：保护性耕作对雷州和大埔的土壤容重和孔隙度均无显著影响，而少耕模式对土壤有机质和大团聚体含量的影响存在地域差异。在雷州试验区，少耕模式总体上增加了土壤有机质和大团聚体的含量，增幅最高分别可达48.8%和17.4%；而在大埔试验区，有机质略有降低，大团聚体含量无显著变化。另外，耕作方式对水稻产量产生显著的影响，在雷州和大埔试验区，双季稻产量均为少耕模式下最高（p<0.05），增幅最高可达12.7%；免耕模式略高于传统耕作。少耕模式能减缓南方地区因降雨充沛导致的淋溶、地表径流和氮磷流失，在一定程度上减少土壤侵蚀，进而增加水稻产量。该研究表明短期的保护性耕作模式（2 a）对土壤结构的影响并不显著，但少耕模式是南方双季稻区相对较优的耕作方式。研究结果对探索不同耕作模式下提升稻田土壤肥力和作物产量具有实践意义。

关键词: 耕作模式, 双季稻, 土壤结构, 土壤有机质, 水稻产量

CLC Number:

S344
X171.3

DU Minghui, LI Boxin, YU Yingde, TAO Lin, FAN Shixian, YU Minnan, YU Xiaowen, ZOU Shujun, HUANG Deyin. Effects of Soil Properties and Yield of Double-Cropping Rice in Southern China under Conservation Tillage Mode[J]. Ecology and Environment, 2025, 34(4): 521-533.

杜明慧, 李伯欣, 余英德, 陶琳, 范世献, 余敏男, 于晓雯, 邹淑君, 黄德银. 保护性耕作对南方双季稻田土壤性质及产量的影响[J]. 生态环境学报, 2025, 34(4): 521-533.

Figures/Tables 11

References 39

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试验区	耕作模式	容重/ (g∙cm⁻³)	有机质质量分数/ (g·kg⁻¹)	孔隙度/ %	>0.25 mm大团聚体质量分数/%
雷州	免耕	1.27a	41.2a	51.9a	51.7a	48.3a
	少耕	1.26a	42.2a	52.6a	53.1a	46.9a
	传统耕作	1.28a	40.3a	51.6a	49.9a	50.1a
大埔	免耕	1.28a	26.1a	51.8a	59.6a	40.4a
	少耕	1.28a	29.5a	51.6a	60.2a	39.8a
	传统耕作	1.29a	28.1a	51.5a	58.9a	41.1a

试验区	耕作模式	容重/ (g∙cm⁻³)	有机质质量分数/ (g·kg⁻¹)	孔隙度/ %	>0.25 mm大团聚体质量分数/%
雷州	免耕	1.27a	41.2a	51.9a	51.7a	48.3a
	少耕	1.26a	42.2a	52.6a	53.1a	46.9a
	传统耕作	1.28a	40.3a	51.6a	49.9a	50.1a
大埔	免耕	1.28a	26.1a	51.8a	59.6a	40.4a
	少耕	1.28a	29.5a	51.6a	60.2a	39.8a
	传统耕作	1.29a	28.1a	51.5a	58.9a	41.1a

年份	耕作模式	>0.25 mm大团聚体质量分数/%		<0.25 mm微团聚体质量分数/%
年份	耕作模式	早稻	晚稻	早稻	晚稻
2019	免耕	46.0±10.4ab	45.8±7.04b	54.0±10.4ab	54.3±7.04a
	少耕	58.5±8.66a	60.6±4.10a	41.5±8.66b	39.4±4.10b
	传统耕作	41.1±5.86b	49.7±7.76b	58.9±5.86a	50.3±7.78a
2020	免耕	47.3±3.27b	45.1±3.42a	52.8±3.27a	54.9±3.37a
	少耕	61.6±6.01a	42.0±3.80a	38.4±6.01b	58.1±3.80a
	传统耕作	56.1±7.28ab	48.8±5.81a	43.9±7.28ab	51.3±5.79a

年份	耕作模式	>0.25 mm大团聚体质量分数/%		<0.25 mm微团聚体质量分数/%
年份	耕作模式	早稻	晚稻	早稻	晚稻
2019	免耕	46.0±10.4ab	45.8±7.04b	54.0±10.4ab	54.3±7.04a
	少耕	58.5±8.66a	60.6±4.10a	41.5±8.66b	39.4±4.10b
	传统耕作	41.1±5.86b	49.7±7.76b	58.9±5.86a	50.3±7.78a
2020	免耕	47.3±3.27b	45.1±3.42a	52.8±3.27a	54.9±3.37a
	少耕	61.6±6.01a	42.0±3.80a	38.4±6.01b	58.1±3.80a
	传统耕作	56.1±7.28ab	48.8±5.81a	43.9±7.28ab	51.3±5.79a

年份	耕作模式	>0.25 mm大团聚体质量分数/%		<0.25 mm微团聚体质量分数/%
年份	耕作模式	早稻	晚稻	早稻	晚稻
2019	免耕	52.5±5.15a	39.8±3.42a	47.6±5.15a	60.3±3.42a
	少耕	43.1±5.68a	40.8±6.04a	56.9±5.68a	59.2±6.04a
	传统耕作	46.9±4.51a	36.1±9.46a	53.1±4.51a	63.9±11.2a
2020	免耕	59.6±5.18a	43.1±1.80a	40.4±5.18a	57.0±1.78a
	少耕	63.8±9.17a	42.9±4.64a	36.6±9.17a	57.2±4.67a
	传统耕作	56.9±3.97a	47.7±2.75a	43.1±3.97a	52.4±2.75a

Effects of Soil Properties and Yield of Double-Cropping Rice in Southern China under Conservation Tillage Mode

保护性耕作对南方双季稻田土壤性质及产量的影响

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耕作模式	水稻产量
	2019年		2020年
	早稻	晚稻	早稻	晚稻
免耕	5796.0±187b	6631.5±208b	7650.0±309b	6739.5±337ab
少耕	6187.5±220a	6873.0±398a	7950.0±208a	6861.0±291a
传统耕作	5488.5±401c	6177.0±342c	7575.0±310b	6526.5±285b

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耕作模式	水稻产量/(kg·hm⁻²)
	2019年		2020年
	早稻	晚稻	早稻	晚稻
免耕	6315.0±124b	5949.0±220b	7311.0±253b	5799.0±197b
少耕	6658.5±248a	6349.5±252a	7698.0±193a	6049.5±234a
传统耕作	6258.0±162b	5976.0±204b	7276.5±232b	5676.0±239b

耕作模式	水稻产量/(kg·hm⁻²)
	2019年		2020年
	早稻	晚稻	早稻	晚稻
免耕	6315.0±124b	5949.0±220b	7311.0±253b	5799.0±197b
少耕	6658.5±248a	6349.5±252a	7698.0±193a	6049.5±234a
传统耕作	6258.0±162b	5976.0±204b	7276.5±232b	5676.0±239b