填闲作物替代有机肥对设施土壤氮磷淋洗的影响

doi:10.7668/hbnxb.20193774

摘要/Abstract

摘要：

为控制设施蔬菜管理体系中有机肥用量、降低设施土壤氮磷负荷、减少设施氮磷面源污染风险,以研究区域农民习惯有机肥用量为对照处理(FP),农民习惯有机肥用量减施50%为有机肥减量处理(FP-M),在有机肥减量处理基础上,利用夏季揭棚休闲季种植饲草玉米(FP-M+C)、饲草高粱(FP-M+S)和草黑豆(FP-M+L),且在下茬蔬菜定植前将其原位还田作为填闲处理,采用原位收集淋洗液的方法,通过3 a田间定位试验,研究填闲作物替代有机肥对设施土壤氮磷淋洗量、有机质含量及其剖面硝态氮、有效磷含量和蔬菜产量的影响。结果表明,与农民习惯有机肥用量处理(FP)相比,有机肥减量(FP-M)及其填闲饲草玉米(FP-M+C)、饲草高粱(FP-M+S)和草黑豆处理(FP-M+L)对蔬菜产量无显著影响,FP-M+C和FP-M+S处理显著提高了0~40 cm土壤有机质含量;与FP处理相比,FP-M、FP-M+C、FP-M+S和FP-M+L处理在设施休闲季总氮淋洗量最高降幅分别为13.9%,59.5%,65.4%和54.5%,在蔬菜生长季最高降幅分别达38.3%,48.5%,39.0%和24.0%;与FP处理相比,FP-M、FP-M+C、FP-M+S和FP-M+L处理在设施休闲季总磷淋洗量最高降幅分别为42.3%,53.9%,45.4%和49.1%,在蔬菜生长季最高降幅达37.7%,33.8%,27.7%和26.3%;与FP处理相比,FP-M、FP-M+C、FP-M+S和FP-M+L处理显著降低了80~200 cm土层硝态氮( $NO 3 -$ -N)和20~80 cm土层有效磷(Olsen-P)含量。利用设施休闲季种植填闲作物并将其原位还田,不仅能提升0~40 cm土层土壤有机质含量,起到替代有机肥效果,而且可降低土壤氮磷淋洗、减少设施蔬菜氮磷面源污染风险。

关键词: 填闲作物, 有机肥, 设施土壤, 氮磷淋洗

Abstract:

In order to control the amount of organic manure in the greenhouse vegetable management system,reduce the load of nitrogen and phosphorus in the greenhouse soil and reduce the risk of non-point source pollution of nitrogen and phosphorus in the greenhouse vegetable,a 3-year field experiment,was conducted,and a total of 5 treatments were set.They were the farmers' traditional amount of organic manure in this study area(FP,i.e.the control treatment),the amount of 50% of farmers' traditional amount of organic manure(FP-M,i.e organic manure reduction treatment),and catch crop planted in the fallow period on the basis of the FP-M treatment with forage maize,forage sorghum and legumes incorporation(FP-M+C,FP-M+S and FP-M+L,respectively).In FP-M+C,FP-M+S and FP-M+L treatment,the straw was returned in situ before vegetable transplanting.The leaching liquor was collected in situ,and nitrogen and phosphorus leaching amount,soil organic matter, $NO 3 -$ -N,Olsen-P and vegetable yield were measured,to study the effect of substitution of catch crops for organic manure during the fallow period.The results showed that,there was no difference in vegetable yield between FP treatment and FP-M,FP-M+C,FP-M+S and FP-M+L treatment.However,FP-M+C and FP-M+S treatments had significantly higher organic matter content in 0—40 cm soil compare to FP treatment.Compared with FP treatment,the leaching amount of total nitrogen in the FP-M,FP-M+C,FP-M+S and FP-M+L treatment showed a significant decrease in the fallow period,and decreased by as much as 13.9%,59.5%,65.4% and 54.5%,respectively;in the vegetable growing period,and decreased by as much as 38.3%,48.5%,39.0% and 24.0%,respectively.Compared with FP treatment,the leaching amount of total phosphorus in the FP-M,FP-M+C,FP-M+S and FP-M+L treatment showed a significant decrease in the fallow period,and decreased by as much as 42.3%,53.9%,45.4% and 49.1%,respectively;in the vegetable growing period,and decreased by as much as 37.7%,33.8%,27.7% and 26.3%,respectively.The $NO 3 -$ -N and Olsen-P contents soil profile of the FP-M,FP-M+C,FP-M+S and FP-M+L treatments were significantly decreased compared with FP treatment,in 80—200 cm and 20—80 cm,respectively.Therefore,that reducing 50% of the organic manure by farmers' practice and planting catch crops in the fallow period and returning the straw in situ before vegetable transplanting can increase organic matter content in 0—40 cm soil in the study area.Obviously,the organic manure can be substituted with catch crops.It reduces the risk of nitrogen and phosphorus pollution in greenhouse vegetable while decreasing nitrogen and phosphorus leaching.

Key words: Catch crops, Organic manure, Greenhouse soil, Nitrogen and phosphorus leaching

王立革, 焦晓燕, 郭珺, 王劲松, 武爱莲, 王媛, 董二伟, 韩雄. 填闲作物替代有机肥对设施土壤氮磷淋洗的影响[J]. 华北农学报, 2023, 38(6): 108-117. doi: 10.7668/hbnxb.20193774.

WANG Lige, JIAO Xiaoyan, GUO Jun, WANG Jinsong, WU Ailian, WANG Yuan, DONG Erwei, HAN Xiong. Effects of Substitution of Catch Crops for Organic Manure on Nitrogen and Phosphorus Leaching in Greenhouse Soil[J]. Acta Agriculturae Boreali-Sinica, 2023, 38(6): 108-117. doi: 10.7668/hbnxb.20193774.

http://www.hbnxb.net/CN/Y2023/V38/I6/108

图/表 9

表1 0~100 cm土壤剖面硝态氮和Olsen-P含量

Tab.1

NO 3 -

-N and Olsen-P contents of the tested soils in 0—100 cm depth mg/kg

指标 Index	土层深度/cm Soil depth
指标 Index	0~20	20~40	40~60	60~80	80~100
$NO 3 -$ -N	239.0	247.5	134.7	143.5	112.6
Olsen-P	285.1	230.3	33.1	21.5	12.5

表1 0~100 cm土壤剖面硝态氮和Olsen-P含量

Tab.1

NO 3 -

-N and Olsen-P contents of the tested soils in 0—100 cm depth mg/kg

指标 Index	土层深度/cm Soil depth
指标 Index	0~20	20~40	40~60	60~80	80~100
$NO 3 -$ -N	239.0	247.5	134.7	143.5	112.6
Olsen-P	285.1	230.3	33.1	21.5	12.5

表2 各处理氮、磷投入量

Tab.2 N and P input of different treatments kg/hm²

处理 Treatments	氮投入量N input						磷投入量P input
	有机肥提供的N N provided by manure			无机肥提供的N N provided by chemical fertilizer			有机肥提供的P P provided by manure			无机肥提供的P P provided by chemical fertilizer
		第1年	第2年	第3年	第1年	第2年	第3年	第1年	第2年	第3年	第1年	第2年	第3年
FP	892.5	612.0	612.0	531.0	434.1	432.0	306.6	234.0	234.0	221.5	199.9	203.1
FP-M	446.3	306.0	306.0	265.5	217.1	216.0	153.3	117.0	117.0	110.8	100.0	101.6
FP-M+C	446.3	306.0	306.0	265.5	217.1	216.0	153.3	117.0	117.0	110.8	100.0	101.6
FP-M+S	446.3	306.0	306.0	265.5	217.1	216.0	153.3	117.0	117.0	110.8	100.0	101.6
FP-M+L	446.3	306.0	306.0	265.5	217.1	216.0	153.3	117.0	117.0	110.8	100.0	101.6

图1 不同处理对黄瓜产量的影响不同小写字母表示处理间在5%的差异显著。图2—3同。

Fig.1 Effects of different treatments on cucumber yield Different lowercase letters indicate significant differences among different treatments at 5% level.The same as Fig.2—3.

表3 不同填闲作物地上部生物量、氮磷含量及吸收量

Tab.3 Biomass,content of N and P,accumulation of N and P uptake produced by different catch crops

指标 Index	处理 Treatment	2018年 In 2018	2019年 In 2019	2020年 In 2020
生物量/(t/hm²)	FP-M+C	7.8±0.6a	6.9±0.3a	10.5±0.9a
Biomass	FP-M+S	7.5±0.7a	6.6±0.2a	11.6±0.7a
	FP-M+L	3.1±0.1b	2.9±0.1b	4.7±0.4b
氮含量/(g/kg)	FP-M+C	18.8±1.0b	26.1±1.8b	19.7±0.9b
N content	FP-M+S	15.8±1.4b	22.2±1.2b	16.0±1.3b
	FP-M+L	31.4±2.1a	34.5±4.4a	30.0±2.3a
磷含量/(g/kg)	FP-M+C	2.4±0.1a	4.2±0.4a	6.4±0.2a
P content	FP-M+S	2.3±0.1a	3.9±0.4a	5.6±0.7a
	FP-M+L	3.3±1.1a	4.6±0.1a	5.6±0.2a
氮吸收量/(kg/hm²)	FP-M+C	147.2±11.6a	180.0±19.6a	207.1±12.8a
N uptake	FP-M+S	120.8±13.9a	146.9±12.9a	180.0±19.5a
	FP-M+L	96.6±6.8b	99.5±8.2b	140.0±3.5b
磷吸收量/(kg/hm²)	FP-M+C	18.7±2.4a	29.0±2.8a	67.7±7.2a
P uptake	FP-M+S	16.4±2.1a	25.6±3.4a	63.2±10.3a
	FP-M+L	10.3±3.5b	13.4±0.6b	26.3±3.3b

表4 不同处理土壤有机质含量

Tab.4 Effects of different treatments on soil organic matter content g/kg

处理 Treatment	0~20 cm有机质含量 0—20 cm organic matter content			20~40 cm有机质含量 20—40 cm organic matter content
处理 Treatment	2018年 In 2018	2019年 In 2019	2020年 In 2020	2018年 In 2018	2019年 In 2019	2020年 In 2020
FP	35.7±0.89b	37.0±0.47b	36.7±0.42bc	15.7±0.50b	15.6±0.47b	17.0±0.82b
FP-M	34.5±0.82b	35.6±0.51b	35.6±0.47c	15.9±0.38b	15.3±0.40b	16.3±0.91b
FP-M+C	38.5±0.63a	39.3±0.44a	38.4±0.38a	17.7±0.35a	19.2±0.81a	19.7±0.74a
FP-M+S	38.5±0.62a	39.2±0.85a	38.6±0.65a	17.7±0.83a	19.5±0.70a	19.5±0.27a
FP-M+L	37.7±0.57a	38.6±0.54a	37.8±0.46ab	19.1±0.43a	18.9±0.13a	17.2±0.58b

图2 休闲期和生长期不同处理总氮淋洗量

Fig.2 Total amount of N leaching under different treatments during the fallow period and growth period

图3 休闲期和生长期不同处理总磷淋洗量

Fig.3 Total amount of P leaching under different treatments during the fallow period and growth period

图4 不同处理0~200 cm土壤剖面硝态氮分布

Fig.4 Effects of different treatments nitrate distribution in 0—200 cm soil profile

图5 不同处理0~80 cm土壤剖面Olsen-P含量

Fig.5 Effects of different treatments Olsen-P distribution in 0—80 cm soil profile

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