施用有机肥对我国大豆产量及土壤养分的影响

doi:10.13304/j.nykjdb.2022.0077

中国农业科技导报 ›› 2023, Vol. 25 ›› Issue (8): 148-156.DOI: 10.13304/j.nykjdb.2022.0077

• 生物制造资源生态 • 上一篇

施用有机肥对我国大豆产量及土壤养分的影响

张晨阳¹^,²(), 徐明岗¹^,²^,³(), 王斐², 李然³, 孙楠³()

^1.山西农业大学资源环境学院，山西太谷 030800
^2.山西农业大学生态环境产业技术研究院，土壤环境与养分资源山西省重点实验室，太原 030031
^3.中国农业科学院农业资源与农业区划研究所，农业农村部耕地质量监测与评价重点实验室，北京 100081

收稿日期:2022-01-28 接受日期:2022-06-21 出版日期:2023-08-20 发布日期:2023-09-07
通讯作者: 徐明岗,孙楠
作者简介:张晨阳E-mail：1518405024@qq.com
基金资助:
国家自然科学基金项目(42177341);国家重点研发计划项目(2021YFD1901205)

Effects of Manure Application on Soybean Yield and Soil Nutrients in China

Chenyang ZHANG¹^,²(), Minggang XU¹^,²^,³(), Fei WANG², Ran LI³, Nan SUN³()

^1.College of Resources and Environment，Shanxi Agricultural University，Shanxi Taigu 030800，China
^2.Shanxi Province Key Laboratory of Soil Environment and Nutrient Resources，Institute of Eco-environment and Industrial Technology，Shanxi Agricultural University，Taiyuan 030031，China
^3.Key Laboratory of Cultivated Land Quality Monitoring and Evaluation of Ministry of Agriculture and Rural Affairs，Institute of Agricultural Resources and Regional Planning，Chinese Academy of Agricultural Sciences，Beijing 100081，China

Received:2022-01-28 Accepted:2022-06-21 Online:2023-08-20 Published:2023-09-07
Contact: Minggang XU,Nan SUN

摘要/Abstract

摘要：

施用有机肥有助于增加大豆产量和提升土壤肥力。然而受区域、施肥量、施肥类型等影响，全国大豆产量和土壤肥力差异均较明显，但造成这些差异的原因尚不清楚。为探明全国不同区域、管理措施条件下，施用有机肥对大豆产量和土壤肥力的影响以及影响增产效果的主要因素，在全国尺度上收集数据进行整合分析。按筛选标准，获得施有机肥对大豆产量影响的文献37篇，119组有效数据；对大豆土壤养分影响的文献11篇，148组有效数据。采用增强回归树（boosted regression tree，BRT）模型量化气候因素、土壤性状和施肥措施对大豆增产效果影响的重要程度。结果表明，不同区域施用有机肥后大豆平均增产12.9%，其中南方增产最高（18.7%），其次为华北（14.8%）、西北（13.6%）和东北（12.0%）。有机肥施用量>5 000 kg·hm^-2时，大豆可增产18.5%。施用牛粪后，大豆可增产24.9%，猪粪次之（17.6%），其次为商品有机肥（15.3%）、鸡粪（12.7%）和生物有机肥（8.8%）。不施肥时，大豆平均产量2 036 kg·hm^-2，单施有机肥后其平均产量增加至2 452 kg·hm^-2，增幅20.4%；单施化肥时，大豆平均产量2 410 kg·hm^-2，有机无机肥配施后其平均产量增加至2 630 kg·hm^-2，增幅9.1%。施用有机肥显著提升土壤速效磷（43.5%）、全磷（13.3%）和有机质含量（11.0%），对速效钾（9.4%）、碱解氮（3.4%）、pH（2.1%）及全钾含量（1.2%）提升则不显著。基于BRT结果表明，BRT模型解释了我国大豆产量差异的52.83%，其中有机肥施肥量对大豆产量影响最大，占变异的47.0%，其次是土壤性状（41.0%）和气候因素（12.0%）。总体来说，施用有机肥（包括单施有机肥和有机无机肥配施）可显著增加大豆产量，在南方增产率最高，以牛粪增产效益最为明显，并且大豆产量受有机肥施用量影响最大。此外，施用有机肥可显著提升大豆土壤速效磷、全磷及有机质含量。

关键词: 大豆, 产量, 有机肥, 土壤养分, 整合分析

Abstract:

Application of manure can increase soybean yield and soil fertility. There are significant differences in soybean yield and soil fertility in China due to the influence of region， application rate of manure， type of manure etc. However， the reasons for these differences are still not clear. In order to find out the effect of manure fertilizer application on soybean yield and soil fertility in different regions and management measures in China， and the main factors of yield increase effect， this study collected data on a national scale for integrated analysis. According to the searching criteria， 37 literatures including 119 groups of data on the effect of manure application on soybean yield and 11 literatures including 148 groups of data on the effects of manure application on soil nutrients were obtained. The enhanced boosted regression tree （BRT） model was used to quantify the importance of climate factors， soil properties and manure application measures on soybean yield increase. The average soybean yield increased by 12.9% after application of manure in different regions， with the highest yield in south China （18.7%） and followed by North China （14.8%）， Northwest China （13.6%） and Northeast China （12.0%）. When the application rate of manure was more than 5 000 kg·hm^-2， the increase of soybean yield was 18.5%. Soybean yield increased by 24.9% after the application of cow manure， followed by the application of pig manure （17.6%）， commercial manure （15.3%）， chicken manure （12.7%） and manure （8.8%）. The average soybean yield was 2 224 kg·hm^-2with no fertilizer， whereas it increased by 20.4% to the amount 2 518 kg·hm^-2 with applying manure alone. The average soybean yield was 2 259 kg·hm^-2 under the application of chemical fertilizer， whereas it increased by 9.1% to the amount 2 558 kg·hm^-2 under the combined application of manure and chemical fertilizer. Manure application significantly increased soil available P （43.5%）， total P （13.3%） and organic matter （11.0%）， but had no significant effect on soil available K （9.4%）， alkali hydrolyzable nitrogen （3.4%）， pH （2.1%） and total K （1.2%）. Based on the BRT results， the BRT model explained 52.83% of soybean yield differences in China. Among them， the application rate of manure had the greatest impact on soybean yield， accounting for 47.0% of the variation， followed by soil properties （41.0%） and climate factors （12.0%）. In general， the application of manure （including the single application of manure and combined application of manure and chemical fertilizer） could significantly increase soybean yield， with the largest increase in South China and with the highest increasing production benefit under the application of cow manure. Soybean yield was mostly affected by the application rate of manure. Additionally， the available P， total P and organic matter contents in soybean soil significantly increased under the application of manure.

Key words: soybean, yield, manure, soil nutrients, meta-analysis

中图分类号:

S158

张晨阳, 徐明岗, 王斐, 李然, 孙楠. 施用有机肥对我国大豆产量及土壤养分的影响[J]. 中国农业科技导报, 2023, 25(8): 148-156.

Chenyang ZHANG, Minggang XU, Fei WANG, Ran LI, Nan SUN. Effects of Manure Application on Soybean Yield and Soil Nutrients in China[J]. Journal of Agricultural Science and Technology, 2023, 25(8): 148-156.

图/表 8

表1 收集的全国各个地区的数据量分布

Table 1 Distribution areas of data collected from whole China

地区 Region	总计 Total	分布 Distribution
地区 Region	总计 Total	地区 Region	数量 Number
东北 Northeast	79	吉林 Jilin	2
		辽宁 Liaoning	1
		黑龙江 Heilongjiang	76
华北 North China	10	河南 Henan	1
		安徽 Anhui	8
		内蒙古 Inner Mongolia	1
西北 Northwest	22	新疆 Xinjiang	14
西北 Northwest	22	陕西 Shaanxi	8
南方 Southern	8	湖北 Hubei	2
		湖南 Hunan	1
		福建Fujian	5

图1 施用有机肥后大豆产量响应比的分布

Fig. 1 Distribution of soybean yield response ratio with manure application

图2 施用有机肥不同区域大豆的增产效果注：括号内数值为样本量。

Fig. 2 Yield enhancement effect of soybean in different regions with application of manureNote： Value in bracket is sample number.

图3 不同有机肥施肥量的大豆增产效果注：括号内数值为样本量。

Fig. 3 Yield enhancement effect of soybean with different application rate of manureNote： Value in bracket is the sample number.

图4 不同有机肥类型下的大豆增产效果注：括号内数值为样本量。

Fig. 4 Yield enhancement effect of soybean with different type of manureNote： Value in bracket is the sample number.

图5 有机肥不同配施措施下的大豆增产效果注：箱形图的上下误差线分别代表最大值和最小值，中间实线和方块分别表示平均数和中位数，不同小写字母表示处理间的产量差异显著（P<0.05）。

Fig. 5 Yield enhancement effect of soybean with different manure application measuresNote：The upper and lower error line represent the maximum and minimum， respectively； the solid line and squares in the box represent the mean value and median value， respectively； the different lowercase letters indicate significant differences in yield between treatments （P<0.05）。

图6 施用有机肥的土壤养分和pH变化注：土壤养分括号内数值为样本量。

Fig. 6 Change of soil nutrients and pH with application of manureNote： Value in bracket is the sample number.

图7 大豆产量变化的驱动因素

Fig. 7 Drivers of changes in soybean yield

参考文献 54

1	李运美,王明扬,董春辉. 2020年大豆进口首次超亿吨国产大豆行业如何破困局[J].黑龙江粮食,2021(9): 21-23.
	LI Y M, WANG M Y, DONG C H. How to break the predicament of the domestic soybean industry when soybean imports exceed 100 million tons for the first time in 2020 [J]. J. Heilongjiang Grain, 2021(9):21-23.
2	莫飞,王桂霞,胡明阳.基于成本视角的东北地区大豆生产现状分析[J].大豆科学,2020,39(6):947-953.
	MO F, WANG G X, HU M Y. Analysis of the current situation of soybean production in Northeast China from the perspective of cost [J]. Soybean Sci., 2020, 39(6):947-953.
3	ZHU Z L, JU X T, CUI Z L, et al., Reducing environmental risk by improving N management in intensive Chinese agricultural systems [J]. Proc. Natl. Acad. Sci. USA, 2009, 106(9):3041-3046.
4	任科宇,徐明岗,张露,等.我国不同区域粮食作物产量对有机肥施用的响应差异[J].农业资源与环境学报, 2021, 38(1): 143-150.
	REN K Y, XU M G, ZHANG L, et al.. Response differences of grain crop yields to organic fertilizer application in different regions of my country [J]. J. Agric. Resour. Environ., 2021, 38(1): 143-150.
5	王道中,花可可,郭志彬.长期施肥对砂姜黑土作物产量及土壤物理性质的影响[J].中国农业科学,2015,48(23):4781-4789.
	WANG D Z, HUA K K, GUO Z B. Effects of long-term fertilization on crop yield and soil physical properties in lime concretion black soil [J]. Sci. Agric. Sin., 2015, 48(23):4781-4789.
6	王小林,张盼盼,纪晓玲,等.黄土塬区施肥策略对大豆生物量分配及转化积累的影响[J].中国农学通报,2021,37(33):23-29.
	WANG X L, ZHANG P P, JI X L, et al., Effects of fertilization strategies on soybean biomass allocation and transformation accumulation in Loess Plateau [J]. China Agric. Sci. Bull., 2021, 37(33):23-29.
7	李蕊,杨越,李彦生,等.基于玉米-大豆轮作的不同施肥体系对大豆开花后根系形态及产量的影响[J].中国油料作物学报,2018, 40(1): 64-73.
	LI R, YANG Y, LI Y S, et al.. Effects of different fertilization systems on characteristics of roots after flowering and yield in soybean based on corn-soybean rotation [J]. Chin. J. Oil Crop Sci., 2018, 40(1):64-73.
8	张亚杰,邓少虹,李伏生,等.喀斯特地区春玉米套作夏大豆下作物产量和农田碳贮量对有机肥与化肥配施的响应[J].南方农业学报,2015,46(9):1584-1590.
	ZHANG Y J, DENG S H, LI F S, et al.. The effects of organic fertilizer and chemical fertilizer on crop yield and farmland carbon storage under intercropping of spring maize with summer soybean in Karst area [J]. Guangxi Agric. Sci., 2015, 46(9):1584-1590.
9	朱宝国,于忠和,王囡囡,等.有机肥和化肥不同比例配施对大豆产量和品质的影响[J].大豆科学,2010,29(1):97-100.
	ZHU B G, YU Z H, WANG N N, et al., Effects of different proportions of organic fertilizer and chemical fertilizer on yield and quality of soybean [J]. Soybean Sci., 2010, 29(1):97-100.
10	严君,陈旭,邹文秀,等.长期配施有机肥对大豆产量的影响[J].大豆科学,2019,38(6):943-948.
	YAN J, CHEN X, ZOU W X, et al.. Effects of long-term combined application of organic fertilizer on soybean yield [J]. Soybean Sci., 2019, 38(6):943-948.
11	宁川川,王建武,蔡昆争.有机肥对土壤肥力和土壤环境质量的影响研究进展[J].生态环境学报,2016,25(1):175-181.
	NING C C, WANG J W, CAI K Z. The effects of organic fertilizers on soil fertility and soil environmental quality:a review [J]. Ecol. Environ., 2016, 25(1):175-181.
12	CONACHER J, CONACHER A. Organic farming and the environment, with particular reference to Australia: a review [J]. Biol. Agric. Hortic., 1998, 16(2):145-171.
13	周伯瑜,杨子江.论有机肥料在农业生态系统中的地位和作用[J].生态学杂志,1992(3):55-57, 76.
	ZHOU B Y, YANG Z J. Role and function of organic fertilizer in agroecosystem [J]. Chin. J. Ecol., 1992(3):55-57, 76.
14	何电源,王凯荣.论有机肥在农业生态系统中的地位和作用[J].农业现代化研究,1989(2):12-15.
	HE D Y, WANG K R. On the position and function of organic fertilizer in agricultural ecosystem [J]. Res. Agric. Modernization, 1989(2):12-15.
15	温延臣,李燕青,袁亮,等.长期不同施肥制度土壤肥力特征综合评价方法[J].农业工程学报,2015,31(7):91-99.
	WEN Y C, LI Y Q, YUAN L, et al.. Comprehensive assessment methodology of characteristics of soil fertility under different fertilization regimes in North China [J]. Trans. Chin. Soc. Agric. Eng., 2015, 31(7):91-99.
16	李彦,孙翠平,井永苹,等.长期施用有机肥对潮土土壤肥力及硝态氮运移规律的影响[J].农业环境科学学报,2017,36(7):1386-1394.
	LI Y, SUN C P, JING Y P, et al.. Effects of long-term application of organic fertilizer on soil fertility and nitrate nitrogen transport in fluvo aquic soil [J]. J. Agro-Environ. Sci., 2017,36(7):1386-1394.
17	TAOVA S. Get Data Digitizing Program Code: Description, Testing, Training [M]. Vienna: International Atomic Energy Agency, International Nuclear Data Committee, 2013:1-216.
18	ROSENBERG M S, ADAMS D C, GUREVITCH J. Metawin: Statistical Software for Meta-analysis with Resampling Tests [M]. America: Sinauer Associates Inc, 1997:1-146.
19	CURTIS P S, WANG X. A meta-analysis of elevated CO₂ effects on woody plant mass, form, and physiology [J]. Oecologia, 1998, 113(3):299-313.
20	HEDGES L V, CURTIS G P S. The meta-analysis of response ratios in experimental ecology [J]. Ecology, 1999, 80(2):1150-1156.
21	PALLMANN P. Applied meta-analysis with R [J]. J. Appl. Statistics, 2015, 42(3):914-915.
22	何寒青,陈坤.Meta分析中的异质性检验方法[J].中国卫生统计,2006(6):486-487, 490.
	HE H Q, CHEN K. Methods for measuring heterogeneity in a meta-analysis [J]. Chin. J. Health Statistics, 2006(6):486-487, 490.
23	张法伟,李红琴,李文清,等.基于增强回归树模型的三江源国家公园表层土壤有机碳及全氮密度的特征评估和等级区划[J].生态学报,2022,42(14):5586-5592.
	ZHANG F W, LI H Q, LI W Q, et al.. Characteristic evaluation and grading of topsoil organic carbon and total nitrogen density in Sanjiangyuan National Park based on enhanced regression tree model [J]. Acta Ecol. Sin., 42(14):5586-5592,
24	韩逸,江叶枫,郭熙,等.基于增强回归树的鄱阳湖平原区耕地土壤钾素空间变异影响因素研究[J].植物营养与肥料学报,2020,26(4):622-634.
	HAN Y, JIANG Y F, GUO X, et al.. Study on the influencing factors of spatial variation of soil potassium in cultivated land in Poyang Lake Plain based on enhanced regression trees [J]. J. Plant Nutr. Fert., 2020, 26(4):622-634.
25	ELITH J, LEATHWICK J R, HASTIE T. A working guide to boosted regression trees [J]. J. Anim. Ecol., 2008, 77(4):802-813.
26	郝瑞莲,张全民,韩英.土壤水份胁迫对夏大豆养分吸收及产量影响的研究[J].大豆通报,1998(4):12.
	HAO R L, ZHANG Q M, HAN Y. Effects of soil water stress on nutrient absorption and yield of summer soybean [J]. Soybean Bull., 1998(4):12.
27	程桂敏,王国林,陈道荣.大豆高产的气象原因与生产对策[J].中国农业气象,1996(3):28-29, 32.
	CHENG G M, WANG G L, CHEN D R. Meteorological reasons and production countermeasures for high soybean yield [J]. Chin. J. Agrometeorol.,1996(3):28-29, 32.
28	REY A, PETSIKOS C, JARVIS P G . et al .. Effect of temperature and moisture on rates of carbon mineralization in a mediterranean oak forest soil under controlled and field conditions [J]. Eur. J. Soil Sci., 2005, 56(5):589-599.
29	夏国芳,张雷,魏湜,等.温度与土壤水分对有机碳分解速率的影响[J].中国生态农业学报,2007(4):57-59.
	XIA G F, ZHANG L, WEI S, et al., Effects of temperature and soil moisture on the decomposition rate of organic carbon [J]. Chin. J.. Eco-Agric., 2007(4):57-59.
30	葛序娟,潘剑君,邬建红,等培养温度对水稻土有机碳矿化参数的影响研究 [J].土壤通报.2015,46(3):562-569.
	GE X J, PAN J J, WU J H, et al., Study on the effect of culture temperature on the mineralization parameters of organic carbon in paddy soil [J]. Soil Bull., 2015, 46(3):562-569.
31	王丹,吕瑜良,徐丽,等水分和温度对若尔盖湿地和草甸土壤碳矿化的影响 [J].生态学报,2013,33(20):6436-6443.
	WANG D, LU Y J, XU L, et al.. Effects of water and temperature on soil carbon mineralization in Zoige wetland and meadow [J]. Acta Ecol. Sin., 2013, 33(20):6436-6443.
32	BUYANOVSKY G A, ASLAM M, WAGNER G H. Carbon turnover in soil physical fractions [J]. Soil Sci. Soc. Am. J., 1994, 58(4):1167-1173.
33	王长军,王肇陟,王世荣.生物有机肥、腐殖酸对水稻产量和土壤化学性质的影响[J].江苏农业科学,2016,44(1): 93-95.
	WANG C J, WANG Z Z, WANG S R. Effects of bio-organic fertilizer and humic acid on rice yield and soil chemical properties [J]. Jiangsu Agric. Sci., 2016, 44(1):93-95.
34	聂俊,邱俊荣,史亮亮,等.有机肥和化肥配施对抛栽水稻产量、品质及钾吸收转运的影响[J].江苏农业科学,2016,44(2):122-125.
	NIE J, QIU J R, SHI L L, et al.. Effects of combined application of organic fertilizer and chemical fertilizer on yield, quality and potassium absorption and transfer of throw-planted rice [J]. Jiangsu Agric. Sci., 2016, 44(2):122-125.
35	毛霞丽,陆扣萍,何丽芝,等.长期施肥对浙江稻田土壤团聚体及其有机碳分布的影响[J].土壤学报,2015,52(4):828-838.
	MAO X L, LU K P, HE L Z, et al., Effects of long-term fertilization on soil aggregates and their organic carbon distribution in paddy fields in Zhejiang [J]. Acta Pedol. Sin., 2015, 52(4):828-838.
36	霍琳,王成宝,逄焕成,等.有机无机肥配施对新垦盐碱荒地土壤理化性状和作物产量的影响[J].干旱地区农业研究,2015,33(4):105-111.
	HUO L, WANG C B, PANG H C, et al., Effects of combined application of organic and inorganic fertilizers on physical and chemical properties and crop yields in alkali-saline soil [J]. Agric. Res. Arid Areas, 2015,33(4):105-111.
37	马俊永,曹彩云,郑春莲,等.长期施用化肥和有机肥对土壤有机碳和容重的影响[J].中国土壤与肥料,2010(6):38-42.
	MA J Y, CAO C Y, ZHENG C L, et al.. Effects of long-term application of chemical and organic fertilizers on soil organic carbon and bulk density [J]. Soil Fert. Sci. China,2010(6):38-42.
38	袁家富.西瓜氮钾适宜施用量的研究[J].土壤通报,1996(1):38-41.
	YUAN J F. Study on the appropriate application rate of nitrogen and potassium in watermelon [J]. Chin. J. Soil Sci., 1996(1):38-41.
39	国辉,袁红莉,耿兵,等.牛粪便资源化利用的研究进展[J].环境科学与技术,2013,36(5):68-75, 107.
	GUO H, YUAN H L, GENG B, et al.. Research progress in resource utilization of cattle manure [J]. Environ. Sci. Technol., 2013, 36(5):68-75, 107.
40	WALTER M, SHANNON K, CAROLINA P, et al.. Treatment of dairy manure effluent using freshwater algae:algal productivity and recovery of manure nutrients using pilotscale algal turf scrubbers [J]. Bioresour. Technol., 2008,99(17):8137-8142.
41	盛斌.牛粪的处理与资源化利用[J].安徽农学通报,2019,25(11):132-134.
	SHENG B. Treatment and resource utilization of cow dung [J]. Anhui Agric. Sci. Bull., 2019, 25(11):132-134.
42	李书田,刘荣乐,陕红.我国主要畜禽粪便养分含量及变化分析[J].农业环境科学报,2009,28(1):179-184.
	LI S T, LIU R L, SHAN H.Analysis on the nutrient content and change of the main livestock and poultry manure in my country [J]. J. Agric. Environ. Sci., 2009, 28(1):179-184.
43	田艳洪,刘元英,张文钊,等.不同时期施用氮肥对大豆根瘤固氮酶活性及产量的影响[J].东北农业大学学报,2008(5):15-19.
	TIAN Y H, LIU Y Y, ZHANG W Z, et al.. Effects of nitrogen fertilizer application on soybean nodule nitrogenase activity and yield in different periods [J]. J. Northeast Agric.Univ., 2008(5):15-19.
44	赵明,陈雪辉,赵征宇,等.鸡粪等有机肥料的养分释放及对土壤有效铜, 锌, 铁, 锰含量的影响[J].中国生态农业学报,2007,15(2):47-50.
	ZHAO M, CHEN X H, ZHAO Z Y, et al., Releasing of N, P and K oforganic fertilizers and their effects on the contents of available Cu,Zn, Fe and Mn in soil [J]. Chin. J. Eco-Agric., 2007, 15(2):47-50.
45	刘博,卫玲,肖俊红,等.5种元素对大豆生长和产量的影响[J].山西农业科学,2019,47(10):1806-1810.
	LIU B, WEI L, XIAO J H, et al.. Effects of five elements on soybean growth and yield [J]. Shanxi Agric. Sci., 2019, 47(10):1806-1810.
46	冯敏铃,李盛安,刘铭扬,等.畜禽有机肥中营养成分及重金属含量研究[J].现代农业科技,2021(21):172-174.
	FENG M L, LI S G, LIU M Y, et al.. Research on nutrient components and heavy metal content in organic fertilizers for livestock and poultry [J]. Modern Agric. Sci. Technol., 2021(21):172-174.
47	王家军,刘杰,张瑞萍,等.沼渣与化肥配施对大豆田土壤理化性质和土壤微生物的影响[J].安徽农业科学,2012,40(13):7763-7765.
	WANG J J, LIU J, ZHANG R P, et al.. Effects of biogas residue and chemical fertilizer on soil physicochemical properties and soil microorganisms in soybean field [J]. J. Anhui Agric. Sci., 2012, 40(13):7763-7765.
48	刘杰,王大蔚,裴占江,等.有机无机复混肥对大豆根际环境的影响[J].大豆科学,2010,29(4):730-732..
	LIU J, WANG D W, PEI Z J, et al., Effects of organic and inorganic compound fertilizer on rhizosphere environment of soybean [J]. Soybean Sci., 2010, 29(4):730-732.
49	郭颖,赵牧秋,吴蕊,等.有机肥对设施菜地土壤—植物系统硝酸盐迁移累积的影响[J].农业环境科学学报,2008(5):1831-1835.
	GUO Y, ZHAO M, WU R, et al., Effects of organic fertilizer on nitrate migration and accumulation in soilplant system of greenhouse vegetable plot [J]. J. Agro-Environ. Sci., 2008, 27(5):183-1835.
50	孙倩倩,王正银,赵欢,等.定位施肥对紫色菜园土磷素状况的影响[J].生态学报,2012,32(8):2539-2549.
	SUN Q Q, WANG Z Y, ZHAO H, et al.. Effects of location fertilization on soil phosphorus status in purple garden [J]. Acta Ecol. Sin., 2012, 32(8):2539-2549.
51	BHATTACHARYYA R, KUNDU SPRAKASH V, et al.. Sustainability under combined application of mineral and organic fertilizers in a rainfed soybean wheat system of the Indian Himalayas [J]. Eur. J. Agron., 2008, 28(1):33-46.
52	鲁如坤.土壤磷素化学研究进展[J].土壤学进展,1990(6):1-5, 19.
	LU R K. Advances in soil phosphorus chemistry [J]. Adv. Soil Sci., 1990(6):1-5, 19.
53	高菊生,黄晶,董春华,等.长期有机无机肥配施对水稻产量及土壤有效养分影响[J].土壤学报,2014,51(2):314-324.
	GAO J S, HUANG J, DONG C H, et al.. Effects of long-term combined application of organic and inorganic fertilizers on rice yield and soil available nutrients [J]. Acta Pedol. Sin., 2014, 51(2):314-324.
54	史吉平,张夫道,林葆.长期施用氮磷钾化肥和有机肥对土壤氮磷钾养分的影响[J].土壤肥料,1998(1):7-10.
	SHI J P, ZHANG F D, LIN B. Effects of long-term application of NPK fertilizers and organic fertilizers on soil NPK nutrients [J]. Soil Fert., 1998(1):7-10.

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施用有机肥对我国大豆产量及土壤养分的影响

Effects of Manure Application on Soybean Yield and Soil Nutrients in China

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