浅埋滴灌水氮配施对冬小麦生长发育、产量及水分利用效率的影响

doi:10.6048/j.issn.1001-4330.2024.05.003

新疆农业科学 ›› 2024, Vol. 61 ›› Issue (5): 1057-1066.DOI: 10.6048/j.issn.1001-4330.2024.05.003

• 作物遗传育种·种质资源·分子遗传学 • 上一篇下一篇

浅埋滴灌水氮配施对冬小麦生长发育、产量及水分利用效率的影响

谢忠(), 叶含春(), 王振华, 李海强, 刘健, 陈睿, 许宇双

石河子大学水利建筑工程学院/现代节水灌溉兵团重点实验室/农业农村部西北绿洲节水农业重点实验室,新疆石河子 832000

收稿日期:2023-10-25 出版日期:2024-05-20 发布日期:2024-07-09
通信作者: 叶含春(1966-),男,新疆库尔勒人,教授,硕士生导师,研究方向为水资源开发利用,(E-mail)739301184@qq.com
作者简介:谢忠(1996-),男,江西抚州人,硕士研究生,研究方向为干旱区节水灌溉,(E-mail)xz5250207@163.com
基金资助:
国家自然科学基金项目(52279040);第三次新疆综合科学考察项目(2022xjkk0500);新疆生产建设兵团重点领域创新团队项目(2019CB004)

Effects of water and nitrogen application on winter wheat growth, yield, and water use efficiency under shallow buried drip irrigation

XIE Zhong(), YE Hanchun(), WANG Zhenhua, LI Haiqiang, LIU Jian, CHEN Rui, XU Yushuang

College of Water & Architectural Engineering/Key Laboratory of Modern Water-Saving Irrigation of Xinjiang Production & Construction Group/Key Laboratory of Northwest Oasis Water-Saving Agriculture, Ministry of Agriculture and Rural Affairs, Shihezi Xinjiang 832000, China

Received:2023-10-25 Published:2024-05-20 Online:2024-07-09
Correspondence author: YE Hanchun(1966-), males, from Korla, Xinjiang, professor, master instructor, research direction:the development and utilization of water resources,(E-mail)739301184@qq.com
Supported by:
National Natural Science Foundation of China(52279040);The Third Xinjiang Scientific Expedition Program(2022xjkk0500);Innovation Team Project in Key Areas of XPCC(2019CB004)

摘要/Abstract

摘要：

【目的】研究滴灌带浅埋、水氮配施对冬小麦生长发育、产量及水分利用效率的影响。【方法】试验为完全区组设计,设置3个因素:覆土深度(0和5 cm)、灌水量(270、315和360 mm)、施氮量(195、255和315 kg/hm²)。【结果】在浅埋滴灌(5 cm)下,灌溉定额为315 mm、施氮量255 kg/hm²时,冬小麦产量、水分利用效率及氮肥偏生产力提升最明显。浅埋滴灌使冬小麦株高和叶面积指数分别提高5.58%和16.77%,产量、水分利用效率与氮肥偏生产力分别显著提高8.32%、8.20%和8.16%。浅埋滴灌较不覆土滴灌(0 cm)处理净收益平均增收1 092 元/hm²,浅埋滴灌下灌水315 mm、施氮255 kg/hm²净收益最高(10 883 元/hm²)。【结论】冬小麦较优的灌溉施肥方案为浅埋滴灌灌水315 mm,施氮255 kg/hm²。

关键词: 冬小麦; 浅埋滴灌; 水氮配施; 水分利用效率; 产量

Abstract:

【Objective】This project aims to discuss the effects of shallow burial drip irrigation belt, irrigation and nitrogen application on the growth, yield and water use of winter wheat.【Methods】In this study, three factors were set up: soil depth (0 and 5 cm), irrigation amount (270,315 and 360 mm), and nitrogen application (195,255 and 315 kg/hm²).【Results】The results showed that, when the irrigation quota was 315 mm and the nitrogen application rate was 255 kg/hm², the yield, irrigation water use efficiency and nitrogen fertilizer partial productivity increased most obviously.Shallow buried drip irrigation increased the plant height and leaf area index of winter wheat by 5.58% and 16.77%, respectively, and the yield, irrigation water use efficiency and nitrogen partial factor productivity significantly increased by 8.32%, 8.20% and 8.16%, respectively.The net income of shallow buried drip irrigation increased by 1,092 yuan per hectare on average compared with that of no soil cover drip irrigation (0 cm).The net income of shallow buried drip irrigation with 315 mm of water and 255 kg/hm² of nitrogen was the highest, (10,883 yuan/hm²).【Conclusion】The best irrigation and fertilization schemes are as follows: 315 mm of irrigation water and 255 kg/hm² of nitrogen under shallow drip irrigation.

Key words: winter wheat; shallow buried drip irrigation; water and nitrogen combined application; water use efficiency; yield

中图分类号:

S512

谢忠, 叶含春, 王振华, 李海强, 刘健, 陈睿, 许宇双. 浅埋滴灌水氮配施对冬小麦生长发育、产量及水分利用效率的影响[J]. 新疆农业科学, 2024, 61(5): 1057-1066.

XIE Zhong, YE Hanchun, WANG Zhenhua, LI Haiqiang, LIU Jian, CHEN Rui, XU Yushuang. Effects of water and nitrogen application on winter wheat growth, yield, and water use efficiency under shallow buried drip irrigation[J]. Xinjiang Agricultural Sciences, 2024, 61(5): 1057-1066.

图/表 8

参考文献 35

[1]	范玲玲. 中国小麦空间格局演变及区域水资源利用效应研究[D]. 北京: 中国农业科学院, 2021.
	FAN Lingling. Spatio-Temporal Variation of Wheat Cultivation and It’s Effects on Regional Water Resources Utilization in China[D]. Beijing: Chinese Academy of Agricultural Sciences, 2021.
[2]	张龑, 王永刚, 肖菁, 等. 引进春小麦品种(系)芽期抗旱性评价[J]. 新疆农业科学, 2020, 57(12): 2186-2196. DOI
	ZHANG Yan, WANG Yonggang, XIAO Jing, et al. Evaluation of drought resistance of introduced spring wheat varieties (lines) at bud stage[J]. Xinjiang Agricultural Sciences, 2020, 57(12): 2186-2196. DOI
[3]	张彩霞, 张芮, 王引弟, 等. 水肥气热耦合在农业灌溉中的研究进展[J]. 水利规划与设计, 2020,(9): 66-70, 159.
	ZHANG Caixia, ZHANG Rui, WANG Yindi, et al. Research progress of water-fertilizer-gas-heat coupling in agricultural irrigation[J]. Water Resources Planning and Design, 2020,(9): 66-70, 159.
[4]	曹彩云, 党红凯, 郑春莲, 等. 水肥管理模式对小麦氮素吸收及转运的影响[J]. 麦类作物学报, 2022, 42(11): 1367-1380.
	CAO Caiyun, DANG Hongkai, ZHENG Chunlian, et al. Effect of irrigation and fertilizer management mode on nitrogen uptake and transfer of winter wheat[J]. Journal of Triticeae Crops, 2022, 42(11): 1367-1380.
[5]	李越, 李根东, 陈志君, 等. 基于氮收支平衡的河套灌区春小麦农田灌溉和施氮策略[J]. 农业工程学报, 2022, 38(17): 61-72.
	LI Yue, LI Gendong, CHEN Zhijun, et al. Irrigation and N application strategies for spring wheat fields in the Hetao irrigation district based on N balance[J]. Transactions of the Chinese Society of Agricultural Engineering, 2022, 38(17): 61-72.
[6]	Shah A N, Iqbal J, Tanveer M, et al. Nitrogen fertilization and conservation tillage: a review on growth, yield, and greenhouse gas emissions in cotton[J]. Environmental Science and Pollution Research International, 2017, 24(3): 2261-2272. DOI PMID
[7]	Zhang H Z, Zhao Q, Zhong W, et al. Effects of nitrogen fertilizer on photosynthetic characteristics, biomass, and yield of wheat under different shading conditions[J]. Agronomy, 2021, 11(10): 1989.
[8]	张丽霞, 杨永辉, 尹钧, 等. 水肥一体化对小麦干物质和氮素积累转运及产量的影响[J]. 农业机械学报, 2021, 52(2): 275-282, 319.
	ZHANG Lixia, YANG Yonghui, YIN Jun, et al. Effects of drip fertigation on accumulation and translocation of dry matter and nitrogen together with yield in wheat[J]. Transactions of the Chinese Society for Agricultural Machinery, 2021, 52(2): 275-282, 319.
[9]	Akbarzadeh A, Shahnazari A, Ziatabar Ahmadi M, et al. Partial root zone drying increases peppermint essential oil yield and water productivity[J]. Agricultural Water Management, 2022, 263: 107459.
[10]	Wang T, Wang Z, Zhang J, et al. An optimum combination of irrigation amount, irrigation water salinity and nitrogen application rate can improve cotton (for fiber) nitrogen uptake and final yield[J]. Industrial Crops and Products, 2022, 187: 115386.
[11]	张新燕, 王浩翔, 牛文全. 水氮供应对温室滴灌番茄水氮分布及利用效率的影响[J]. 农业工程学报, 2020, 36(9): 106-115.
	ZHANG Xinyan, WANG Haoxiang, NIU Wenquan. Effects of water and N-fertilizer supplies on the distribution and use efficiency of water and nitrogen of drip-irrigated tomato in greenhouse[J]. Transactions of the Chinese Society of Agricultural Engineering, 2020, 36(9): 106-115.
[12]	姚振宪. 我国滴灌创新发展综述[J]. 农业工程, 2022, 12(1): 75-78.
	YAO Zhenxian. Summary of innovation and development of drip irrigation in China[J]. Agricultural Engineering, 2022, 12(1): 75-78.
[13]	Qi Y L, Ossowicki A, Yang X M, et al. Effects of plastic mulch film residues on wheat rhizosphere and soil properties[J]. Journal of Hazardous Materials, 2020, 387: 121711.
[14]	Koskei K, Munyasya A N, Wang Y B, et al. Effects of increased plastic film residues on soil properties and crop productivity in agro-ecosystem[J]. Journal of Hazardous Materials, 2021, 414: 125521.
[15]	Afzal M S, Cheema M J M, Shahid M A, et al. Optimization of subsurface drip lateral depths and irrigation levels for best yield response of onion (allium cepa l.)[J]. The Journal of Animal and Plant Sciences, 2020, 30(3): 702-712.
[16]	葛选良, 杨恒山, 张雨珊, 等. 浅埋滴灌下不同施氮量对玉米产量和花后氮代谢的影响[J]. 植物营养与肥料学报, 2022, 28(9): 1603-1613.
	GE Xuanliang, YANG Hengshan, ZHANG Yushan, et al. Effects of nitrogen application rate on maize yield and nitrogen metabolism after anthesis under shallow buried drip irrigation[J]. Journal of Plant Nutrition and Fertilizers, 2022, 28(9): 1603-1613.
[17]	张雨珊, 杨恒山, 葛选良, 等. 增密种植下浅埋滴灌水氮减量对玉米根、冠物质分配与水氮利用效率的影响[J]. 干旱地区农业研究, 2022, 40(2): 129-136, 196.
	ZHANG Yushan, YANG Hengshan, GE Xuanliang, et al. Effects of reduction of nitrogen and water of shallow drip irrigation on material distribution of root and canopy and utilization efficiency of water and nitrogen of maize under dense planting[J]. Agricultural Research in the Arid Areas, 2022, 40(2): 129-136, 196.
[18]	Wu Y, Bian S F, Liu Z M, et al. Drip irrigation incorporating water conservation measures: effects on soil water-nitrogen utilization, root traits and grain production of spring maize in semi-arid areas[J]. Journal of Integrative Agriculture, 2021, 20(12): 3127-3142.
[19]	Wang S F, Jiao X Y, Guo W H, et al. Adaptability of shallow subsurface drip irrigation of alfalfa in an arid desert area of Northern Xinjiang[J]. PLoS One, 2018, 13(4): e0195965.
[20]	田旭浪, 王振华, 李文昊, 等. 覆土浅埋滴灌对春小麦耗水特性及水分利用效率的影响[J]. 土壤通报, 2022, 53(2): 315-323.
	TIAN Xulang, WANG Zhenhua, LI Wenhao, et al. Effects of shallow drip irrigation with covering soil on water consumption and water use efficiency of spring wheat[J]. Chinese Journal of Soil Science, 2022, 53(2): 315-323.
[21]	薛丽华, 胡锐, 赛力汗, 等. 滴灌量对冬小麦耗水特性和干物质积累分配的影响[J]. 麦类作物学报, 2013, 33(1): 78-83.
	XUE Lihua, HU Rui, SAI Lihan, et al. Effect of different amount of drip irrigation on water consumption characteristics and dry matter accumulation and distribution in winter-wheat[J]. Journal of Triticeae Crops, 2013, 33(1): 78-83.
[22]	雷宏军, 金翠翠, 潘红卫, 等. 水气互作对辣椒根系形态、产量和品质的影响效应[J]. 农业机械学报, 2022, 53(12): 344-352.
	LEI Hongjun, JIN Cuicui, PAN Hongwei, et al. Integrative effects of irrigation and aeration on root morphology, yield and quality of pepper[J]. Transactions of the Chinese Society for Agricultural Machinery, 2022, 53(12): 344-352.
[23]	王振华, 陈潇洁, 吕德生, 等. 水肥耦合对加气滴灌加工番茄产量及品质的影响[J]. 农业工程学报, 2020, 36(19): 66-75.
	WANG Zhenhua, CHEN Xiaojie, LYU Desheng, et al. Effects of water and fertilizer coupling on the yield and quality of processing tomato under aerated drip irrigation[J]. Transactions of the Chinese Society of Agricultural Engineering, 2020, 36(19): 66-75.
[24]	王洋洋, 贺利, 任德超, 等. 基于主成分-聚类分析的不同水分冬小麦晚霜冻害评价[J]. 作物学报, 2022, 48(2): 448-462. DOI
	WANG Yangyang, HE Li, REN Dechao, et al. Evaluations of winter wheat late frost damage under different water based on principal component-cluster analysis[J]. Acta Agronomica Sinica, 2022, 48(2): 448-462. DOI
[25]	李易玲, 彭西红, 陈平, 等. 减量施氮对套作玉米大豆叶片持绿、光合特性和系统产量的影响[J]. 中国农业科学, 2022, 55(9): 1749-1762. DOI
	LI Yiling, PENG Xihong, CHEN Ping, et al. Effects of reducing nitrogen application on leaf stay-green, photosynthetic characteristics and system yield in maize-soybean relay strip intercropping[J]. Scientia Agricultura Sinica, 2022, 55(9): 1749-1762. DOI
[26]	Hu T, Li K, Xiong K, et al. Research Progress on Water-Fertilizer Coupling and Crop Quality Improvement and Its Implication for the Karst Rock Desertification Control[J]. Agronomy, 2022, 12(4): 903.
[27]	段佳宏, 李楠楠, 王军, 等. 滴灌带埋设深度对无膜棉产量形成的影响[J]. 棉花学报, 2021, 33(5): 404-411. DOI
	DUAN Jiahong, LI Nannan, WANG Jun, et al. Effect of embedded depth of drip irrigation belt on the yield of cotton without plastic mulching[J]. Cotton Science, 2021, 33(5): 404-411.
[28]	王荣莲, 张智超, 嘉晓辉, 等. 地下滴灌湿润体变化规律及滴灌带筛选初步研究[J]. 节水灌溉, 2017,(11): 34-37.
	WANG Ronglian, ZHANG Zhichao, JIA Xiaohui, et al. A preliminary study on wetting body change rule under subsurface drip irrigation and selection of drip irrigation belt[J]. Water Saving Irrigation, 2017,(11): 34-37.
[29]	Resende R S, Cintra F L D, Pacheco E P, et al. Soil penetration resistance and sugarcane rooting under subsuperficial drip irrigation levels[J]. Sugar Tech, 2023, 25(1): 99-109.
[30]	房琴, 高影, 王红光, 等. 密度和施氮量对超高产夏玉米干物质积累和产量形成的影响[J]. 华北农学报, 2015, 30(S1): 133-138. DOI
	FANG Qin, GAO Ying, WANG Hongguang, et al. Effect of planting density and nitrogen rate on dry matter accumulation and yield formation of super highly-yielding summer-sowing maize[J]. Acta Agriculturae Boreali-Sinica, 2015, 30(S1): 133-138.
[31]	李雪, 尹光华, 马宁宁, 等. 浅埋滴灌水氮运筹对春玉米产量及水分利用效率的影响[J]. 干旱地区农业研究, 2019, 37(2): 172-178.
	LI Xue, YIN Guanghua, MA Ningning, et al. Effects of water and nitrogen management on yield and water use efficiency of spring maize under shallow-buried drip irrigation[J]. Agricultural Research in the Arid Areas, 2019, 37(2): 172-178.
[32]	Li X B. Salt leaching and Iris germanica L. growth in two coastal saline soils under drip irrigation with saline water[J]. Scientia Horticulturae, 2018, 237: 164-168.
[33]	樊吴静, 杨鑫, 何虎翼, 等. 水氮耦合对旱藕产量、生理特性和土壤理化性状的影响[J]. 西南农业学报, 2022, 35(5): 1069-1078.
	FAN Wujing, YANG Xin, HE Huyi, et al. Effect of water and nitrogen coupling on the yield and physiology characteristics of edible canna and the physical and chemical properties of soil[J]. Southwest China Journal of Agricultural Sciences, 2022, 35(5): 1069-1078.
[34]	贾琼, 史海滨, 李瑞平, 等. 西辽河平原覆膜和浅埋对滴灌玉米生长的影响[J]. 水土保持学报, 2021, 35(3): 296-303, 311.
	JIA Qiong, SHI Haibin, LI Ruiping, et al. Effects of mulched and soil covered drip irrigation on growth of maize in West Liaohe Plain[J]. Journal of Soil and Water Conservation, 2021, 35(3): 296-303, 311.
[35]	张明伟, 杨恒山, 范秀艳, 等. 浅埋滴灌下水氮减量对春玉米干物质积累及水氮利用效率的影响[J]. 玉米科学, 2021, 29(2): 149-156.
	ZHANG Mingwei, YANG Hengshan, FAN Xiuyan, et al. Effect of reduction of nitrogen and irrigation on dry matter accumulation and utilization efficiency of water and nitrogen of spring maize in shallow drip irrigation[J]. Journal of Maize Sciences, 2021, 29(2): 149-156.

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生育期 Growth period	日期 Date (M/D)	灌溉、施肥周期 Irrigation and fertilization cycle(d)	灌溉、施肥比例 Ration of irrigation and fertilization (%)	灌溉、施肥次数 Frequency of irrigation and fertilization
苗期-返青期 Seedling- Greening	9/18~4/3	198	12.5	1
拔节期 Jointing	4/3~5/6	32	37.5	3
开花期 Anthesis	5/6~5/26	20	25.0	2
灌浆期 Grain filling	5/26~6/15	20	25.0	2
成熟期 Maturity	6/15~7/2	18	0	0
全生育期 Whole growth	9/18~7/2	288	100.0	8

生育期 Growth period	日期 Date (M/D)	灌溉、施肥周期 Irrigation and fertilization cycle(d)	灌溉、施肥比例 Ration of irrigation and fertilization (%)	灌溉、施肥次数 Frequency of irrigation and fertilization
苗期-返青期 Seedling- Greening	9/18~4/3	198	12.5	1
拔节期 Jointing	4/3~5/6	32	37.5	3
开花期 Anthesis	5/6~5/26	20	25.0	2
灌浆期 Grain filling	5/26~6/15	20	25.0	2
成熟期 Maturity	6/15~7/2	18	0	0
全生育期 Whole growth	9/18~7/2	288	100.0	8

处理 Treatments	穗粒数 Grains per spike (粒/穗)	千粒重 1000-grain weight (g)	穗数 Spike number (穗/m²)	产量 Yield (kg/hm²)	灌溉水利用效率 Irrigation water-use efficiency (kg/m³)	氮肥偏生产力 Nitrogen partial factor productivity (kg/kg)
W₁N₁S₀	30.67±1.15^l	40.66±0.57^l	447.00±8.19^j	5 173.52±151.71^l	1.92±0.06^ghi	26.53±0.78^e
W₁N₁S₅	34.00±1.73^kl	41.99±0.86^kl	462.67±6.03^ij	5 502.42±146.69^k	2.04±0.05^def	28.22±0.75^d
W₁N₂S₀	35.00±1.00^k	42.68±0.44^jk	471.00±9.64^ij	5 622.57±224.71^jk	2.08±0.08^cde	22.05±0.88^gh
W₁N₂S₅	39.67±2.08^ij	45.48±1.47^hi	482.33±17.62^hi	6 108.30±177.24^gh	2.26±0.07^b	23.95±0.70^f
W₁N₃S₀	31.33±0.58^l	41.36±1.23^kl	489.67±8.50^ghi	5 415.77±144.45^kl	2.01±0.05^efg	17.19±0.46^k
W₁N₃S₅	35.67±0.58^k	44.34±0.88^ij	499.67±6.51^gh	5 804.55±147.00^ij	2.15±0.05^c	18.43±0.47^j
W₂N₁S₀	42.00±2.00^ghi	47.33±0.94^fg	467.00±21.63^ij	6 011.98±245.64^hi	1.91±0.08^hi	30.83±1.26^d
W₂N₁S₅	49.33±2.52^cde	51.67±0.73^bcd	503.00±12.29^fgh	6 244.05±102.98^fgh	1.98±0.03^fgh	32.02±0.53^b
W₂N₂S₀	51.33±1.15^bcd	52.3±0.84^bc	514.00±8.89^efg	6 648.41±227.93^cde	2.11±0.07^cd	26.07±0.89^e
W₂N₂S₅	55.33±1.15^a	55.13±0.62^a	551.67±20.21^bcd	7 568.59±123.86^a	2.40±0.04^a	29.68±0.49^c
W₂N₃S₀	44.67±4.73^fg	49.3±0.99^e	528.33±19.5^def	6 437.12±83.92^ef	2.04±0.03^def	20.44±0.27ⁱ
W₂N₃S₅	52.33±2.08^abc	52.69±0.98^bc	558.00±18.00^bc	6 698.17±226.33^cde	2.13±0.07ⁱ	21.26±0.72ⁱ
W₃N₁S₀	37.00±2.00^jk	45.00±1.71^hi	487.33±13.05^ghi	6 310.72±94.12^fg	1.75±0.03^j	32.36±0.48^b
W₃N₁S₅	40.33±1.53^hij	46.66±1.25^gh	514.67±19.43^efg	6 784.84±152.55^cd	1.89±0.04^hi	34.79±0.78^a
W₃N₂S₀	46.67±1.53^ef	50.15±0.73^de	536.33±17.79^cde	6 852.10±217.22^c	1.90±0.06^hi	26.87±0.85^e
W₃N₂S₅	53.67±1.53^ab	53.45±1.17^ab	571.00±17.69^ab	7 680.14±84.23^a	2.13±0.02^cd	30.12±0.33^c
W₃N₃S₀	43.67±1.53^fgh	48.84±1.34^ef	548.33±13.65^bcd	6 537.93±105.72^def	1.82±0.03^ij	20.76±0.34ⁱ
W₃N₃S₅	48.67±2.08^de	51.18±0.33^cd	589.33±10.02^a	7 195.18±185.19^b	1.96±0.05^b	22.84±0.59^fg
显著性Significance
灌水量W	277.985^**	355.677^**	93.992^**	297.578^**	59.922^**	285.025^**
施氮量N	77.739^**	82.082^**	68.320^**	89.862^**	84.570^**	109.311^**
覆土深度S	96.552^**	101.513^**	45.598^**	126.326^**	116.821^**	117.354^**
W×N	5.783^**	5.400^**	2.275 ^ns	2.881^*	2.263^ns	5.891^**
W×S	1.483^ns	1.832^ns	3.372^*	2.756^ns	0.532^ns	2.449^ns
N×S	0.301^ns	0.365^ns	0.013^ns	7.149^**	6.572^**	6.103^**
W×N×S	1.438^ns	1.355^ns	0.248^ns	1.557^ns	1.423^ns	1.335^ns

处理 Treatments	穗粒数 Grains per spike (粒/穗)	千粒重 1000-grain weight (g)	穗数 Spike number (穗/m²)	产量 Yield (kg/hm²)	灌溉水利用效率 Irrigation water-use efficiency (kg/m³)	氮肥偏生产力 Nitrogen partial factor productivity (kg/kg)
W₁N₁S₀	30.67±1.15^l	40.66±0.57^l	447.00±8.19^j	5 173.52±151.71^l	1.92±0.06^ghi	26.53±0.78^e
W₁N₁S₅	34.00±1.73^kl	41.99±0.86^kl	462.67±6.03^ij	5 502.42±146.69^k	2.04±0.05^def	28.22±0.75^d
W₁N₂S₀	35.00±1.00^k	42.68±0.44^jk	471.00±9.64^ij	5 622.57±224.71^jk	2.08±0.08^cde	22.05±0.88^gh
W₁N₂S₅	39.67±2.08^ij	45.48±1.47^hi	482.33±17.62^hi	6 108.30±177.24^gh	2.26±0.07^b	23.95±0.70^f
W₁N₃S₀	31.33±0.58^l	41.36±1.23^kl	489.67±8.50^ghi	5 415.77±144.45^kl	2.01±0.05^efg	17.19±0.46^k
W₁N₃S₅	35.67±0.58^k	44.34±0.88^ij	499.67±6.51^gh	5 804.55±147.00^ij	2.15±0.05^c	18.43±0.47^j
W₂N₁S₀	42.00±2.00^ghi	47.33±0.94^fg	467.00±21.63^ij	6 011.98±245.64^hi	1.91±0.08^hi	30.83±1.26^d
W₂N₁S₅	49.33±2.52^cde	51.67±0.73^bcd	503.00±12.29^fgh	6 244.05±102.98^fgh	1.98±0.03^fgh	32.02±0.53^b
W₂N₂S₀	51.33±1.15^bcd	52.3±0.84^bc	514.00±8.89^efg	6 648.41±227.93^cde	2.11±0.07^cd	26.07±0.89^e
W₂N₂S₅	55.33±1.15^a	55.13±0.62^a	551.67±20.21^bcd	7 568.59±123.86^a	2.40±0.04^a	29.68±0.49^c
W₂N₃S₀	44.67±4.73^fg	49.3±0.99^e	528.33±19.5^def	6 437.12±83.92^ef	2.04±0.03^def	20.44±0.27ⁱ
W₂N₃S₅	52.33±2.08^abc	52.69±0.98^bc	558.00±18.00^bc	6 698.17±226.33^cde	2.13±0.07ⁱ	21.26±0.72ⁱ
W₃N₁S₀	37.00±2.00^jk	45.00±1.71^hi	487.33±13.05^ghi	6 310.72±94.12^fg	1.75±0.03^j	32.36±0.48^b
W₃N₁S₅	40.33±1.53^hij	46.66±1.25^gh	514.67±19.43^efg	6 784.84±152.55^cd	1.89±0.04^hi	34.79±0.78^a
W₃N₂S₀	46.67±1.53^ef	50.15±0.73^de	536.33±17.79^cde	6 852.10±217.22^c	1.90±0.06^hi	26.87±0.85^e
W₃N₂S₅	53.67±1.53^ab	53.45±1.17^ab	571.00±17.69^ab	7 680.14±84.23^a	2.13±0.02^cd	30.12±0.33^c
W₃N₃S₀	43.67±1.53^fgh	48.84±1.34^ef	548.33±13.65^bcd	6 537.93±105.72^def	1.82±0.03^ij	20.76±0.34ⁱ
W₃N₃S₅	48.67±2.08^de	51.18±0.33^cd	589.33±10.02^a	7 195.18±185.19^b	1.96±0.05^b	22.84±0.59^fg
显著性Significance
灌水量W	277.985^**	355.677^**	93.992^**	297.578^**	59.922^**	285.025^**
施氮量N	77.739^**	82.082^**	68.320^**	89.862^**	84.570^**	109.311^**
覆土深度S	96.552^**	101.513^**	45.598^**	126.326^**	116.821^**	117.354^**
W×N	5.783^**	5.400^**	2.275 ^ns	2.881^*	2.263^ns	5.891^**
W×S	1.483^ns	1.832^ns	3.372^*	2.756^ns	0.532^ns	2.449^ns
N×S	0.301^ns	0.365^ns	0.013^ns	7.149^**	6.572^**	6.103^**
W×N×S	1.438^ns	1.355^ns	0.248^ns	1.557^ns	1.423^ns	1.335^ns

处理 Treatments	产出 Output (元/hm²)	投入 Input (元/hm²)	净收益 Net yield (元/hm²)	处理 Treatments	产出 Output (元/hm²)	投入 Input (元/hm²)	净收益 Net yield (元/hm²)
W₁N₁S₀	13 399	8 190	5 210	W₁N₁S₅	14 251	8 415	5 836
W₁N₂S₀	14 562	8 385	6 178	W₁N₂S₅	15 820	8 610	7 211
W₁N₃S₀	14 027	8 580	5 447	W₁N₃S₅	15 034	8 805	6 229
W₂N₁S₀	15 571	8 299	7 272	W₂N₁S₅	16 172	8 524	7 648
W₂N₂S₀	17 219	8 494	8 725	W₂N₂S₅	19 603	8 719	10 883
W₂N₃S₀	16 672	8 689	7 983	W₂N₃S₅	17 348	8 914	8 434
W₃N₁S₀	16 345	9 109	7 236	W₃N₁S₅	17 573	9 334	8 239
W₃N₂S₀	17 747	9 304	8 443	W₃N₂S₅	19 892	9 529	10 363
W₃N₃S₀	16 933	9 499	7 435	W₃N₃S₅	18 636	9 724	8 912

浅埋滴灌水氮配施对冬小麦生长发育、产量及水分利用效率的影响

Effects of water and nitrogen application on winter wheat growth, yield, and water use efficiency under shallow buried drip irrigation

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