茶树水分胁迫建模及试验

doi:10.3969/j.issn.1674-8530.15.0249

摘要
图/表
参考文献
相关文章 (3)

全文: PDF (1421 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要通过观测冬季和春季塑料大棚中不同灌溉条件下茶树的冠层温度、空气温湿度、土壤热流密度、土壤湿度、太阳净辐射照度及风速等因素, 利用Idso经验模式确定了冠气温差的下限方程.通过观察不同水分处理条件下茶树作物水分胁迫指数的日变化和季节变化,得出了反映茶树水分状况的关系曲线.研究分析了Jackson的理论模式与Idso的经验模式反映茶树水分胁迫的差异性,针对于华南地区经常出现的冬旱及春旱,首先通过人工田间数据采集的方法,分9—12月和1—3月2个阶段测量茶树作物水分胁迫指数中所涉及到的各个参数,建立了茶树冬季和春季的作物水分胁迫指数模型.研究结果发现,茶树冬季和春季作物水分胁迫指数模型相差不大,冬季经验模型中,系数A和B的值分别为1.265和-0.220,而春季经验模型中,系数A和B的值分别是1.230和-0.214,这可能与茶树属于多年生植物,冬季和春季叶面积指数等变化不大相关.

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	孙道宗

	王卫星

	唐劲驰
	姜晟

关键词 ：茶树, 冠层温度, 作物水分胁迫, 经验模型, 理论模型

Abstract：The canopy temperature, air temperature and humidity, soil heat flux, soil moisture, net solar radiation, wind speed and other factors are observed when tea trees are growing in a greenhouse under different irrigation conditions in winter and spring, then a lower limit equation of canopy temperature difference is determined by using the Idso empirical model. Finally, the curves for representing tea tree moisture content status are obtained by observing the diurnal and seasonal variation curves of tea crop water stress index(CWSI)under different moisture contents. Additionally, the difference in CWSI between Jackson theoretical model and Idso empirical model is analyzed. Since drought often happens in spring and winter in South China, the field data are collected manually in September-December and January-March next year. The various parameters related to CWSI are extracted, and the water stress index models for winter and spring are developed, respectively. The results reveal that there is no significant difference in tea tree water stress index models between winter and spring. In winter, the coefficients A and B in the model are 1.265 and -0.220, while they are 1.230 and -0.214 in spring. It may be because the tea tree is perennial crop and the leaf area index is similar in spring and winter.

Key words： tea tree canopy temperature crop water stress index experience model theoretical model

收稿日期: 2015-11-16

基金资助:2014年广东省科技计划项目(2013B020314014);国家星火计划项目(2013GA780046)

通讯作者: 王卫星(1963—),男,河北宣化人,教授,博士生导师(通信作者,weixing@scau.edu.cn),主要从事无线传感器网络研究.

作者简介: 孙道宗(1979—),男,安徽怀远人,高级实验师,博士(sundaozong@scau.edu.cn),主要从事农业电气化及自动化研究.

引用本文:

孙道宗^,, 王卫星^,, 唐劲驰, 姜晟. 茶树水分胁迫建模及试验[J]. 排灌机械工程学报, 2017, 35(1): 65-70. SUN Daozong^,, WANG Weixing^,, TANG Jinchi, JIANG Sheng. Modeling and testing of tea tree water stress. Journal of Drainage and Irrigation Machinery Engin, 2017, 35(1): 65-70.

链接本文:

http://zzs.ujs.edu.cn/pgjx/CN/10.3969/j.issn.1674-8530.15.0249 或 http://zzs.ujs.edu.cn/pgjx/CN/Y2017/V35/I1/65

[1]陈四龙,张喜英,陈素英,等. 不同供水条件下冬小麦冠气温差、叶片水势和水分亏缺指数的变化及其相互关系[J]. 麦类作物学报, 2005,25(5):38-43.
　　CHEN Silong, ZHANG Xiying, CHEN Suying, et al. Variation and interrelationship of winter wheat canopy-air temperature difference, leaf water potential and crop water stress index under different water supply conditions[J]. Journal of triticeae crops, 2005,25(5):38-43.(in Chinese)
[2]史宝成,刘钰,蔡甲冰.冠层温度指导冬小麦灌溉的试验研究[J].节水灌溉,2008(4):11-14.
　　SHI Baocheng, LIU Yu, CAI Jiabing. Experimental study on using canopu temperature to guide winter wheat irrigation[J]. Water saving irrigation, 2008(4):11-14.(in Chinese)
[3]TANNER C B, SINCLAIR T R. Efficient water use in crop production: research and re-search?[M]//TAYLOR H M, JORDAN W R, SINCLAIR T R. Limitations to efficient water use in crop production. Madison, WI, USA: American Society of Agronomy, 1983:1-27.
[4]IRMAK S, HAMAN D Z, BASTUG R. Determination of crop water stress index for irrigation timing and yield estimation of corn[J]. Agronomy journal, 2000,92(6):1221-1227.
[5]袁国富,罗毅,孙晓敏,等.作物冠层表面温度诊断冬小麦水分胁迫的试验研究[J].农业工程学报,2002,18(6):13-17.
　　YUAN Guofu, LUO Yi, SUN Xiaomin, et al. Winter wheat water stress detection based on canopy surface temperature[J]. Transactions of the CSAE, 2002,18(6):13-17.(in Chinese)
[6]袁国富,唐登银,罗毅,等.基于冠层温度的作物缺水研究进展[J].地球科学进展,2000,16(1):49-54.
　　YUAN Guofu, TANG Dengyin, LUO Yi, et al. Advances in canopy-temperature-based crop water stress research[J]. Advance in earth sciences, 2000,16(1):49-54.(in Chinese)
[7]HALIM ORTA A, ERDEM Y, ERDEM T. Crop water stress index for watermelon[J]. Scientia horticulturae, 2003,98(2):121-130.
[8]崔晓,许利霞,袁国富,等.基于冠层温度的夏玉米水分胁迫指数模型的试验研究[J].农业工程学报,2005,21(8):22-24.
　　CUI Xiao, XU Lixia, YUAN Guofu, et al. Crop water stress index model for monitoring summer maize water stress based on canopy surface temperature[J]. Transactions of the CSAE, 2005,21(8):22-24.(in Chinese)
　　
[9]WANG Weixing, LUO Xiwen, OU Yinggang, et al. Preliminary research on model for determining crop water stress index of flowering Chinese cabbage based on canopy temperature[J]. Transactions of the CSAE, 2003,19(5):47-50.
[10]EMEKLI Y, BASTUG R, BUYUKTAS D, et al. Evaluation of a crop water stress index for irrigation scheduling of bermudagrass[J]. Agricultural water management, 2007,90(3):205-212.
[11]IDSO S B, JACKSON R D, PINTER JR P J, et al. Normalizing the stress degree day parameter for environmental variability[J]. Agricultural meteorology, 1981,24:45-55.
[12]O′TOOLE J C, REAL J G. Estimation of aerodynamic and crop resistances from canopy temperature[J]. Agronomy journal, 1985,78(2):305-310.
[13]JALALI-FARAHANI H R, SLACK D C, KOPEC D M, et al. Crop water-stress index models for bermudagrass turf: a comparison[J]. Agronomy journal, 1991,85(6):1210-1217.
[14]JACKSON R D, IDSO S B, REGINATO R J, et al. Canopy temperature as a crop water stress indicator[J]. Water resources research, 1981,17(4): 1133-1138.
[15]IDSO S B, CLAWSON K L, ANDERSON M G. Foliage temperature: effects of environmental factors with implications for plant water stress assessment and the CO² climate connection[J]. Water resources research, 1986,22(12):1702-1716.
[16]IDSO S B. Non-water-stressed baselines: a key to measuring and interpreting plant water stress[J]. Agricultural meteorology, 1982,27(1/2):59-70.