氮肥减施及绿肥混作对土壤质量和小麦产量的影响

doi:10.3864/j.issn.0578-1752.2025.22.012

Abstract

Abstract:

【Objective】This study aimed to screen a suitable green manure configuration mode to reduce the amount of nitrogen applied to wheat, so as to provide the theoretical basis and technical support for improving soil quality and increasing wheat yield and stable yield in Qinghai Plateau. 【Method】The split plot experiment was carried out in the experimental base of the Academy of Agricultural and Forestry Sciences of Qinghai University from 2022 to 2023. The main plot was set as nitrogen application level, namely 225 kgN·hm^-2 (N2, customary nitrogen application), and 158 kgN·hm^-2 (N1, 30% reduction of customary nitrogen application); the split plot was divided into four green manure configuration modes, namely common vetch monoculture (CV), common vetch and highland barley mixed cropping (CV×CH), common vetch and hairy vetch mixed cropping (CV×HV), and common vetch and rapeseed mixed cropping (CV×RS). 【Result】The soil bulk density and pH of common vetch mixed with highland barley were 8.6%-10.5% and 3.3%-3.4% lower than those of common vetch monoculture, 3.3%-5.8% and 1.6%-1.9% lower than those of common vetch mixed with hairy vetch, and 4.9%-7.5% and 2.3%-2.4% lower than those of common vetch mixed with rape, respectively. The soil organic matter, total nitrogen, total phosphorus, total potassium, nitrate nitrogen, ammonium nitrogen, available phosphorus and available potassium in the mixed cropping of common vetch were 20.0%-22.3%, 8.3%-9.7%, 11.2%-15.6%, 14.6%-16.4%, 14.8%-20.1%, 16.8%-18.9%, 16.4%-19.4%, 23.8%-24.6% higher than those in the single cropping of common vetch, 12.6%-13.8%, 3.9%-4.2%, 3.1%-4.9%, 4.8%-5.5%, 7.5%-8.2%, 8.2%-8.7%, 6.1%-7.7%, 6.9%-10.7% higher than those of common vetch mixed with hairy vetch, and 26.7%-35.4%, 14.3%-14.4%, 7.0%-8.2%, 7.9%-9.8%, 23.5%-28.0%, 23.5%-25.3%, 11.5%-12.3%, 16.5%-19.6% higher than those of common vetch mixed with rape, respectively. The activities of soil sucrase and catalase were increased by 3.2%-4.1% and 4.5%-4.9%, respectively, in the 30% nitrogen reduction treatment compared with the conventional nitrogen application. In addition, the activities of soil sucrase, urease, catalase, and alkaline phosphatase were increased by 20.1%-24.7%, 10.5%-14.4%, 12.2%-16.9%, and 12.2%-12.6%, respectively, in the common vetch mixed cropping of highland barley compared with the common vetch monoculture, 12.0%-12.5%, 4.2%-5.2%, 6.4%-7.6%, 4.7%-6.2% compared with the common vetch mixed with hairy vetch, and 28.1%-33.6%, 15.2%-19.1%, 18.7%-24.2%, 5.7%-5.8% compared with the common vetch mixed with rape, respectively. The soil quality index of 30% nitrogen reduction treatment was 17.1% higher than that of the traditional nitrogen application. Furthermore, the soil quality index for the intercropping of common vetch with hulless barley and the intercropping of common vetch with hairy vetch were 142.3% and 76.6% higher, respectively, compared with the single cropping of common vetch. Under the condition of a 30% reduction in nitrogen fertilizer application, the wheat grain yield of the treatment with common vetch intercropped with hulless barley did not show significant difference compared to traditional nitrogen application. However, it was 10.4%-12.5% and 4.8%-5.9% higher, respectively, than that of single cropping of common vetch and intercropping of common vetch with hairy vetch. The Mantel test indicates that soil quality index and wheat yield were significantly positively correlated with soil organic matter, total nutrients, available nutrients, and enzyme activity, while they were significantly negatively correlated with soil bulk density and pH. Additionally, the random forest model identified soil organic matter, total nitrogen, ammonium nitrogen, nitrate nitrogen, sucrase activity and urease activity were the key factors influencing wheat yield. 【Conclusion】The 30% nitrogen reduction treatment combined with common vetch mixed with highland barley could improve soil quality and wheat yield by improving soil physical and chemical properties and soil enzyme activity, which could be used as a suitable production mode in Qinghai Plateau.

Key words: nitrogen reduction, green manure, mixed cropping, soil quality, wheat yield

ZHANG MingLong, CHAI Qiang, HAN Mei, FAN ZhiLong, YIN Wen, FAN Hong, HE Wei, SUN YaLi, HU FaLong, TAN Yan. Effects of Nitrogen Fertilizer Reduction and Green Manure Mixed Cropping on Soil Quality and Wheat Yield[J].Scientia Agricultura Sinica, 2025, 58(22): 4718-4731.

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References 43

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年份 Year	施氮水平 N application level	绿肥配置模式 Green manure cropping pattern	硝态氮 NO₃^--N (mg∙kg^-1)	铵态氮 NH₄⁺-N (mg∙kg^-1)	速效磷 Available P (mg∙kg^-1)	速效钾 Available K (mg∙kg^-1)
2022	N2	CV	17.9d	8.2e	9.4cd	173.5d
		CV×CH	20.2b	9.8b	10.8a	214.1a
		CV×HV	18.8c	9.2c	10.2ab	194.5b
		CV×RS	16.0f	7.8f	9.7bcd	175.9d
	N1	CV	17.9d	8.6d	9.6d	170.1d
		CV×CH	21.0a	10.3a	11.2a	214.1a
		CV×HV	19.2c	9.2c	10.5abc	192.2bc
		CV×RS	17.3e	8.2e	10.1bcd	182.0cd
2023	N2	CV	18.5e	8.8d	10.3c	186.0c
		CV×CH	22.5b	10.5a	12.0a	231.2a
		CV×HV	21.2c	9.6b	11.2b	216.6b
		CV×RS	17.8f	8.3f	10.9b	197.6c
	N1	CV	19.4d	9.1c	10.0c	186.9c
		CV×CH	23.2a	10.5a	12.1a	230.6a
		CV×HV	21.3c	9.7b	11.2b	215.4b
		CV×RS	17.9f	8.7e	10.6bc	198.5c
显著性（P值）Significance (P value)
施氮水平N application level (N)			0.061	0.052	0.265	0.977
种植模式 Cropping pattern (C)			0.000	0.000	0.000	0.001
施氮水平×种植模式 N×C			0.018	0.000	0.821	0.801

年份 Year	施氮水平 N application level	绿肥配置模式 Green manure cropping pattern	蔗糖酶 Sucrase (mg∙g^-1∙d^-1)	脲酶 Urease (μg∙g^-1∙d^-1)	过氧化氢酶 Catalase (μmol∙g^-1∙h^-1)	碱性磷酸酶 Alkaline phosphatase (nmol∙g^-1∙h^-1)
2022	N2	CV	12.2d	376.8d	1789.4bcd	181.0d
		CV×CH	14.9a	425.1b	2105.2a	201.0ab
		CV×HV	13.2bc	408.8c	1914.7b	192.4bcd
		CV×RS	11.3e	355.0f	1685.7d	192.3bcd
	N1	CV	12.6cd	376.2d	1869.2bc	183.8cd
		CV×CH	15.1a	436.5a	2172.2a	208.6a
		CV×HV	13.5b	410.1c	2059.8a	193.2bcd
		CV×RS	12.1de	368.6e	1759.4cd	195.1bc
2023	N2	CV	13.4de	410.9de	1963.6bc	191.7c
		CV×CH	16.6a	447.6b	2141.9ab	215.9a
		CV×HV	14.8bc	430.9c	2026.1bc	207.0a
		CV×RS	12.5e	391.2f	1850.3c	203.8bcd
	N1	CV	13.8cd	418.7cd	1999.6bc	192.4bc
		CV×CH	17.5a	469.8a	2303.1a	216.7a
		CV×HV	15.4b	449.5b	2151.5ab	206.4ab
		CV×RS	12.9de	405.0e	1892.2c	204.9bcd
显著性（P值）Significance (P value)
施氮水平N application level (N)			0.035	0.051	0.026	0.560
种植模式 Cropping pattern (C)			0.000	0.000	0.000	0.001
施氮水平×种植模式 N×C			0.509	0.042	0.728	0.926

Effects of Nitrogen Fertilizer Reduction and Green Manure Mixed Cropping on Soil Quality and Wheat Yield

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