Thermal imaging can be used as an indicator of water stress due to the closure of stomatal aperture. In this paper, we analyzed the robustness and sensitivity of thermography of winter wheat in the North China Plain. The seasonal and diurnal variations of Crop Water Stress Index (CWSI) were evaluated. Five treatments were applied by means of irrigation, with plots receiving 100% of ETo(DI), 50%(D50), 16%(D16) and no irrigation(NI). A high correlation was found between stomatal conductance (gs) and CWSI, depending on the phenological stage of the crop with R2 = 0.44 at pre-heading stage and R2 = 0.77 at post-heading stage. In addition, a high correlation between yield and CWSI at different growth stages indicates that thermography can predict yield. Hourly measurements of canopy temperature were taken to study the effect of the time of day on image acquisition and it was found that midday was the most appropriate time. These results should assist in designing precision irrigation scheduling for setting the threshold values.
Keywords: CWSI, Triticum aestivum L., stomatal conductance, canopy temperature, yield
DOI: 10.3965/j.ijabe.20120503.003

Citation: Zia S, Du W Y, Spreer W, Spohrer K, He X K, M

CWSI, Triticum aestivum L., stomatal conductance, canopy temperature, yield

Li J, Inanaga S, Li Z, Eneji A E. Optimizing irrigation scheduling for winter wheat in the North China Plain. Agriculture Water Management, 2005; 76: 8-23.

Zhang J, Sui X, Li B, Su B, Li J, Zhou D. An improved water-use efficiency for winter wheat grown under reduced irrigation. Field Crop Research, 1998; 59: 91-98.

Jinsheng J, Jingjie Y, Changming L.Groundwater regime and calculation of yield response in North China Plain: a case study of Luancheng County in Hebei Province. Journal of Geographical Science, 2002; 12: 217-225.

Grant O M, Tronina Ł, Jones H G, Chaves M M. Exploring thermal imaging variables for the detection of stress responses in grapevine under different irrigation regimes. Journal of Experimental Botany, 2006a; (special edition)1-11.

Spreer W, Ongprasert S, Hegele M, Wünsche J N, Müller J. Yield and fruit development in mango (Mangifera indica L. cv. Chok Anan) under different irrigation regimes. Agriculture Water Management, 2009; 96: 574-584.

Idso S B, Jackson R D, Pinter J P Jr., Reginato R J, Hatfield J L. Normalizing the stress degree day parameter for environmental variability. Agricultural Meteorology, 1981; 24: 45-55.

Patel N R, Mehta A N, Shekh A M . Canopy temperature and water stress quantificaiton in rainfed pigeonpea (Cajanus cajan (L.) Millsp.). Agricultural and Forest Meteorology, 2001; 109: 223-232.

Siddique M R B, Hamid A, Islam M S. Drought stress effects on water relations of wheat. Botanical Bulletin of Academia Sinica, 2000; 41:35-39.

Cifre J, Bota J, Escalona J M, Medrano H, Flexas J. Physiological tools for irrigation scheduling in grapevineVitis vinifera L.) An open gate to improve water-use efficiency. Agriculture, Ecosystem & Environment, 2005; 106: 159-170.

Irmak S, Haman D Z, Bastug R. Determination of crop water stress index for irrigation timing and yield estimation of corn. Agronomy Journal, 2000; 92: 1221-1227.

Jones H G. Use of infrared thermometry for estimation of stomatal conductance as a possible aid to irrigation scheduling. Agricultural and Forest Meteorology, 1999a; 95: 139-149.

Jones H G, Stoll M, Santos T, Sousa C, Chaves M M, Grant O M. Use of infrared thermography for monitoring stomatal closure in the field: application to grapevine. Journal of Experimental Botany, 2002; 53: 2249-2260.

Zia S, Spohrer K, Wenyong D, Spreer W, Romano G, He X, Müller J. Monitoring physiological responses to water stress in two maize varieties by infrared thermography. International Journal of Agricultural & Biological Engineering, 2011; 4: 1-9.

Idso S B, Non-water stressed baselines: A key to measuring and interpreting plant water stress. Agricultural Meteorology, 1982; 27: 59-70.

Jones H G. Use of thermography for quantitative studies of spatial and temporal variation of stomatal conductance over leaf surfaces. Plant Cell Environment, 1999b; 22: 1043-1055.

Bengal A, Agam N, Alchanatis V, Cohen Y, Yermiyahu U, Zipori I, Presnov E, Sprintsin M, Dag A. Evaluating water stress in irrigated olives: correlation of soil water status, tree water status, and thermal imagery. Irrigation Science, 2009; 27: 367-376.

Silva B B, Rao T V R. The CWSI variations of a cotton crop in a semi-arid region of Northeast Brazil. Journal of Arid Environment, 2005; 62:649-659.

Alderfasia A A, Nielsenb D C. Use of crop water stress index for monitoring water status and scheduling irrigation in wheat. Agriculture Water Management, 2001; 47: 69-75.

Yazar A, Howell T A, Dusek D A, Copeland K S. Evaluation of crop water stress index for LEPA irrigated corn. Irrigation Science, 1999; 18: 171-180.

Amani I, Fischer R A, Reynolds M P. Canopy temperature depression association with yield of irrigated spring wheat cultivars in a hot climate. Journal of Agronomy & Crop Science, 1996; 176:119-129.

Chen J, Lin L, Lu G. An index of soil drought intensity and degree: An application on corn and a comparison with CWSI. Agriculture Water Management, 2010; 97: 865-871.

Romano G, Zia S, Spreer W, Sanchez C, Cairns J, Araus J L, Müller J. Use of thermography for high throughput phenotyping of tropical maize adaptation in water stress. Computer & Electronics in Agriculture, 2011; 79: 67–74.

Wang L, Qiu G Y, Zhang X, Chen S. Application of a new method to evaluate crop water stress index. Irrigation Science, 2005; 24: 49-54.

Yuan G, Luo Y, Sun X, Tang D. Evaluation of a crop water stress index for detecting water stress in winter wheat in the North China Plain. Agriculture Water Management, 2004; 64: 29-40.

Tubailesh A S, Sammis T W, Lugg D G. Utilization of thermal infrared thermometry for detection of water stress in spring barley. Agriculture Water Management, 1986; 12:75-85.

Payero J O, Irmak S. Variable upper and lower crop water stress index baselines for corn and soybean. Irrigation Science, 2006; 25: 21-32.

Grant O M, Tronina Ł, Ramalho J C, Besson C K, Lobo-do-Vale R, Pereira J S, Jones H G, Chaves M M. The impact of drought on leaf physiology of Quercus suber L. trees: comparison of an extreme drought event with chronic rainfall reduction. Journal of Experimental Botany, 2010; 61: 4361-4371.

Möller M, Alchanatis V, Cohen Y, Meron M, Tsipris J, Naor A, Ostrovsky V, Sprintsin, M, Cohen S. Use of thermal and visible imagery for estimating crop water status of irrigated grapevine. Journal of Experimental Botany, 2007; 58: 827–838.

Zia S, Spohre, K, Merkt N, Wenyong D, He X, Müller J. Non-invasive water status detection in grapevine (Vitis vinifera L.) by thermography. International Journal of Agricultural & Biological Engineering, 2009; 2: 46-54.

Grant O M, Chaves M M, Jones H G. Optimizing thermal imaging as a technique for detecting stomatal closure induced by drought stress under greenhouse conditions. Physiologia Plantarum 2006b; 127:507-518.

Wanjura D F, Upchurch D R. Canopy temperature characterization of corn and cotton water status. Transactions of the ASAE, 2000; 43: 867-875.

Jackson R D, Reginato R J, Idso S B.Wheat canopy temperature: a practical tool for evaluating water requirements. Water Resources Research, 1977; 17:1133-1138.

Fischer R A. The importance of grain or kernel number in wheat: A reply to Sinclair and Jamieson. Field Crops Research, 2008; 105: 15–21