[1]杨永辉,邬佳宾,武继承,等.不同灌溉方式下氢、氧同位素分布与小麦水分利用特征[J].水土保持研究,2023,30(03):260-267.[doi:10.13869/j.cnki.rswc.2023.03.012]
 YANG Yonghui,WU Jiabin,WU Jicheng,et al.Hydrogen and Oxygen Isotope Distribution and Water Use Characteristics of Wheat Under Different Irrigation Methods[J].Research of Soil and Water Conservation,2023,30(03):260-267.[doi:10.13869/j.cnki.rswc.2023.03.012]
点击复制

不同灌溉方式下氢、氧同位素分布与小麦水分利用特征

《水土保持研究》[ISSN:1005-3409/CN:61-1272/P] 卷: 30 期数: 2023年03期 页码: 260-267 栏目: 出版日期: 2023-04-10
Title:
Hydrogen and Oxygen Isotope Distribution and Water Use Characteristics of Wheat Under Different Irrigation Methods
文章编号:
1005-3409(2023)03-0260-08
作者:
杨永辉1,2,3, 邬佳宾4, 武继承1,2,3, 杨先明5, 高翠民1,2,3, 潘晓莹1,2,3, 何 方1,2,3
(1.河南省农业科学院植物营养与资源环境研究所, 郑州 450002; 2.农业部作物高效用水 原阳科学观测试验站, 河南 原阳 453514; 3.河南省黄河流域节水农业野外科学观测研究站, 河南 原阳 453514; 4.水利部 牧区水利科学研究所, 呼和浩特 010020; 5.河南邦友科技有限公司, 郑州 450001)
Author(s):
YANG Yonghui1,2,3, WU Jiabin4, WU Jicheng1,2,3, YANG Xianming5, GAO Cuimin1,2,3, PAN Xiaoying1,2,3, HE Fang1,2,3
(1.Institute of Plant Nutrition,Agricultural Resources and Environmental Sciences,Henan Academy of Agricultural Sciences,Zhengzhou 450002,China; 2.Yuanyang Experimental Station of Crop Water Use,Ministry of Agriculture,Yuanyang 453514,China; 3.Field Scientific Observation and Research Station of Water-Saving Agriculture in the Yellow River Basin of Henan Province,Yuanyang 453514,China; 4.Institute of Water Resources for Pastoral Area,MWR,Hohhot 010020,China; 5.Henan Bangyou Technology......)
关键词:
滴灌 稳定氢氧同位素 水分运移 冬小麦 水分利用
Keywords:
drip irrigation stable hydrogen and oxygen isotopes moisture movement winter wheat water use
分类号:
S275.3; S275.6
DOI:
10.13869/j.cnki.rswc.2023.03.012
文献标志码:
A
摘要:
[目的]探明不同灌溉方式对小麦水分利用的贡献率及小麦根系吸水规律,可为合理应用灌溉用水提供科学依据。[方法]利用稳定氢氧同位素示踪法,研究了防雨棚条件下常规灌溉(X)与滴灌(D)不同灌水量条件下(X1,D1:15 mm; X2,D2:30 mm; X3,D3:45 mm)冬小麦生长期间土壤水稳定同位素变化特征,以及土壤耗水强度、光合生理特征及水分利用特征。[结果]随小麦生育期的推进,根系吸水逐渐加深。在拔节期小麦主要利用0—20 cm深度的土壤水; 在抽穗期X2,D1和D2处理主要利用了0—20 cm土层的水分,但X1处理主要利用了60—80 cm土层的水分,占53.9%,X3处理主要利用了40—60 cm土层的水分,占77.0%。而D3处理主要利用了0—60 cm土层的水分,占80.0%; 到灌浆期,X1和X2处理主要利用了0—60 cm土层的水分,分别占86.2%和90.6%,而X3处理主要利用了40—60 cm土层的水分,占73.9%。而D1和D2处理不同土层的水分利用比例较均匀,分别介于7.1%~27.8%和13.0%~38.2%之间。D3处理主要利用了20—40 cm土层的水分,占51.0%。除抽穗—灌浆期中水处理(D2)及灌浆—收获期高水处理(D3)外,滴灌均有效降低了小麦的日耗水量。与常规灌溉相比,滴灌D2和D3处理更利于提高小麦的光合速率和叶片水分利用效率。此外,滴灌处理在小麦抽穗期和收获期均有效提高了小麦的生物量。最终,滴灌较常规耕作小麦产量提高了21.6%~28.0%和水分利用效率提高了24.4%~36.7%,均以D2处理最高。相关分析表明:小麦生长过程中,抽穗期0—20 cm土层水分贡献率和灌浆期80—100 cm土层的水分贡献率的提高对于其产量与水分利用效率的提高更为有利。[结论]滴灌更利于提供均匀的水分供给作物,同时减少水分无效蒸发,提高作物产量和水分利用率。
Abstract:
[Objective]Ascertaining the contribution rate of different irrigation methods to wheat water use and the water absorption law of wheat root system can provide a scientific basis for the rational application of irrigation water. [Methods] Based on hydrogen-oxygen stable isotope tracing method, the characteristics of soil water stable isotope change during winter wheat growth under conventional irrigation(X)and drip irrigation(D)(X1, D1:15 mm; X2, D2:30 mm; X3 and D3:45 mm)were studied. [Results] The absorption of water deepened with the advancement of the wheat growth period. Soil moisture in 0—20 cm depth was mainly consumed by wheat in the jointing stage under different treatments. In the heading stage, X2, D1, and D2 treatments mainly used soil moisture in 0—20 cm layer, but X1 treatment mainly used soil moisture in 60—80 cm layer, accounting for 53.9%, and X3 treatment mainly used soil moisture in 40—60 cm, accounting for 77.0%. D3 treatment mainly used soil moisture in 0—60 cm layer accounting for 80.0%. In the filling stage, X1 and X2 treatments mainly used soil moisture in 0—60 cm, accounting for 86.2%, and 90.6%, respectively, while X3 treatment mainly used soil moisture in 40—60 cm layer, accounting for 73.9%. However, the water use ratio of different soil layers of D1 and D2 treatments were more uniform, ranging between 7.1%~27.8% and 13.0%~38.2%, respectively. The D3 treatment mainly utilized the water in the 20—40 cm soil layer, accounting for 51.0%. Drip irrigation, except for D2 and D3 treatments, could effectively reduce the daily water consumption of wheat. Compared with conventional irrigation, D2 and D3 treatments were more beneficial to improve the photosynthetic rate and leaf water use efficiency of wheat. Moreover, drip irrigation treatment effectively improved the wheat biomass during both the heading and harvest periods. Finally, wheat yield and water use efficiency under the drip irrigation condition increased by 21.6%~28.0% and 24.4%~36.7%, respectively, compared with conventional irrigation conditions, and the D2 treatment resulted in the highest among different treatments. The related analysis showed that during the growth process of wheat, the increment of water contribution rate of 0—20 cm layer in the heading growth stage and 80~100 cm layer in the filling growth stage was more conducive to improving the yield and water use efficiency. [Conclusion] Drip irrigation is more conducive to providing uniform water supply to crops, and reducing ineffective evaporation of water and improving crop yield and water utilization.

参考文献/References:

[1] 李晖,周宏飞.稳定性同位素在干旱区生态水文过程中的应用特征及机理研究[J].干旱区地理,2006,29(6):810-816.
[2] 田日昌,陈洪松,宋献方,等.湘西北红壤丘陵区土壤水运移的稳定性同位素特征[J].环境科学,2009,30(9):2747-2754.
[3] 王晶晶.土壤作物系统中水分及其氢氧稳定同位素的动态与农田耗水特征[D].北京:中国农业大学,2015.
[4] 邬佳宾,苗澍,徐冰,等.滴灌紫花苜蓿根层水分稳定同位素特征分析[J].灌溉排水学报,2017,36(7):14-27.
[5] Zhao X, Li F D, Ai Z P, et al. Stable isotope evidences for identifying crop water uptake in a typical winter wheat-summer maize rotation field in the North China Plain[J]. Science of the Total Environment, 2018,618:121-131.
[6] Zhang Y C, Shen Y J, Sun H Y, et al. Evapotranspiration and its partitioning in an irrigated winter wheat field:A combined isotopic and micrometeorologic approach[J]. Journal of Hydrology, 2011,408(3):203-211.
[7] 吴友杰.基于稳定同位素的覆膜灌溉农田SPAC水分传输机制与模拟[D].北京:中国农业大学,2017.
[8] Guo F, Ma J J, Zheng L J, et al. Estimating distribution of water uptake with depth of winter wheat by hydrogen and oxygen stable isotopes under different irrigation depths[J]. Journal of Integrative Agriculture, 2016(15):891-906.
[9] Phillips D L, Gregg J W. Source partitioning using stable isotopes:coping with too many sources[J]. Oecologia, 2003,136(2):261-269.
[10] Ruppenthal M, Oelmann Y, Wilcke W. Isotope ratios of nonexchangeable hydrogen in soils from different climate zones[J]. Geoderma, 2010,155(3/4):231-241.
[11] 周加森,马阳,吴敏,等.不同水肥措施下的冬小麦水氮利用和生物效应研究[J].灌溉排水学报,2019,38(9):36-41.
[12] 邓振镛,张强,王强,等.黄土高原旱塬区土壤贮水量对冬小麦产量的影响[C].中国气象学会年会,2011:5281-5290.
[13] 蒲金涌,王润元,李晓薇,等.甘肃黄土高原土壤水分变化对冬小麦产量的影响[J].地理学报,2012,67(5):710-718.
[15] 张涛,马富裕,郑重,等.滴灌条件下水氮耦合对春小麦光合特性及产量的影响[J].西部农业学报,2010,19(6):69-73.
[15] 位国峰,刘义国,姜雯,等.不同滴灌制度对冬小麦光合特性及水分利用效率的影响[J].华北农学报,2013,28(5):149-156.
[16] Li H R, Mei X R, Wang J D, et al. Drip fertigation significantly increased crop yield, water productivity and nitrogen use efficiency with respect to traditional irrigation and fertilization practices:a meta-analysis in China[J]. Agricultural Water Management, 2021,244:106534.
[17] Kang S Z, Zhang L, Liang Y L, et al. Effects of limited irrigation on yield and water use efficiency of winter wheat in the Loess Plateau of China[J]. Agricultural Water Management, 2002,55:203-216.
[18] Shen X J, Wang G S, Zeleke K T, et al. Crop water production functions for winter wheat with drip fertigation in the North China Plain[J]. Agronomy, 2020,10:876.

相似文献/References:

[1]朱德兰,李昭军,王健,等.滴灌条件下土壤水分分布特性研究[J].水土保持研究,2000,7(01):81.
 ZHU De-lan,LI Zhao-jun,WANG jian,et al.The Research of Distribution Pattern of Water in Soil under the Conditions of Drop Irrigation[J].Research of Soil and Water Conservation,2000,7(03):81.
[2]时光新,王相国,尹绪国.山丘区果园微灌效益初步研究[J].水土保持研究,2001,8(03):52.
 SHI Guang-xin,WANG Xiang-guo,YIN Xu-guo.Primary Study on Efficiency of Microspray Irrigation of Orchard on Hilly Area[J].Research of Soil and Water Conservation,2001,8(03):52.
[3]张振华,蔡焕杰,杨润亚,等.滴灌入渗土壤水分分布的数值研究[J].水土保持研究,2004,11(03):91.
 ZHANG Zhen-hua,CAI Huan-jie,YANG Run-ya,et al.The Water Content Distribution of Trickle Source Infiltration[J].Research of Soil and Water Conservation,2004,11(03):91.
[4]朱连勇,崔春亮.浅谈地下滴灌的堵塞问题及处理方法[J].水土保持研究,2005,12(02):111.
 ZHU Lian-yong,CUI Chun-liang.Discussion on Problem of Block-up in Drip Irrigation Underground and Its Treatment[J].Research of Soil and Water Conservation,2005,12(03):111.
[5]王海江,崔静,侯振安,等.不同品种滴灌棉花水氮效应差异性比较[J].水土保持研究,2011,18(02):152.
 WANG Hai-jiang,CUI Jing,HOU Zhen-an,et al.Comparion of the Effect of Water and Nitrogen on Different Cotton Varieties under Drip Irrigation[J].Research of Soil and Water Conservation,2011,18(03):152.
[6]姚宝林,叶含春,孙三民,等.红枣滴灌条件下灌水水质对土壤盐分分布的影响研究[J].水土保持研究,2011,18(02):218.
 YAO Bao-lin,YE Han-chun,SUN San-min,et al.Research on the Effects of Water Quality on Soil Salt Distribution in Drip Irrigation for Red Jujube[J].Research of Soil and Water Conservation,2011,18(03):218.
[7]柴仲平,王雪梅,孙霞,等.基于灰枣产量和品质的水氮耦合效应研究[J].水土保持研究,2011,18(05):263.
 CHAI Zhong-ping,WANG Xue-mei,SUN Xia,et al.Study on Coupling Effect of Water and N Based on Yield and Quality of Huizao Jujube[J].Research of Soil and Water Conservation,2011,18(03):263.
[8]柴仲平,王雪梅,孙霞,等.水氮耦合对枣树生长与产量的影响[J].水土保持研究,2012,19(02):201.
 CHAI Zhong-ping,WANG Xue-mei,SUN Xia,et al.Influence on Growth and Yield of Zizyphus Jujube under Coupling of Water and Nitrogen[J].Research of Soil and Water Conservation,2012,19(03):201.
[9]张晓伟,黄占斌,李秧秧,等.滴灌条件下玉米的产量和WUE效应研究[J].水土保持研究,1999,6(01):72.
 Zhang Xiaowei,Huang Zhanbin,Li Yangyang,et al.Study on Yield and WUE of Corn Under Drip Irrigation[J].Research of Soil and Water Conservation,1999,6(03):72.
[10]刘雅辉,王秀萍,李强,等.淤泥质滨海重盐土低成本快速脱盐技术研究[J].水土保持研究,2015,22(01):168.
 LIU Yahui,WANG Xiuping,LI Qiang,et al.Study on Rapid Desalting of Muddy Coastal Heavy Solonchack with Low Cost[J].Research of Soil and Water Conservation,2015,22(03):168.

备注/Memo

收稿日期:2022-05-05 修回日期:2022-05-13
资助项目:河南省重大科技专项(221100110700); 河南省农业科学院自主创新资金项目(2023ZC038); 内蒙古自治区科技成果转化专项资金项目(2021CG0003)
第一作者:杨永辉(1978—),男,陕西西安人,博士,副研究员,研究方向为水肥资源利用与管理。E-mail:yangyongh2020@126.com
通信作者:杨先明(1979—),男,河南固始县人,硕士研究生,高级农艺师,主要从事植物营养与新型肥料、土肥检测、农业信息化技术与装备等方面的研究工作。E-mail:277921230@qq.com

更新日期/Last Update: 2023-04-10