Parametrization of lower limit temperature in crop water stress index model: A case study of Quercus variabilis plantation

doi:10.13287/j.1001-9332.202407.025

Abstract

Abstract: The lower limit temperature in the crop water stress index (CWSI) model refers to the canopy temperature (T_c) or the canopy-air temperature differences (dT) under well-watered conditions, which has significant impacts on the accuracy of the model in quantifying plant water status. At present, the direct estimation of lower limit temperature based on data-driven method has been successfully used in crops, but its applicability has not been tes-ted in forest ecosystems. We collected continuously and synchronously T_c and meteorological data in a Quercus variabilis plantation at the southern foot of Taihang Mountain to evaluate the feasibility of multiple linear regression model and BP neural network model for estimating the lower limit temperature and the accuracy of the CWSI indicating water status of the plantation. The results showed that, in the forest ecosystem without irrigation conditions, the lower limit temperature could be obtained by setting soil moisture as saturation in the multiple linear regression mo-del and the BP neural network model with soil water content, wind speed, net radiation, vapor pressure deficit and air temperature as input parameters. Combining the lower limit temperature and the upper limit temperature determined by the theoretical equation to normalize the measured T_c and dT could realize the non-destructive, rapid, and automatic diagnosis of the water status of Q. variabilis plantation. Among them, the CWSI obtained by combining the lower limit temperature determined by the dT under well-watered condition calculated by the BP neural network model and the upper limit temperature was the most suitable for accurate monitoring water status of the plantation. The coefficient of determination, root mean square error, and index of agreement between the calculated CWSI and measured CWSI were 0.81, 0.08, and 0.90, respectively. This study could provide a reference method for efficient and accurate monitoring of forest ecosystem water status.

Key words: crop water stress index, BP neural network model, water diagnosis, lower limit temperature

BA Yinji, LIU Linqi, PENG Qing, ZHANG Gong, LU Sen, LUO Kunshui, ZHANG Jinsong. Parametrization of lower limit temperature in crop water stress index model: A case study of Quercus variabilis plantation[J]. Chinese Journal of Applied Ecology, 2024, 35(7): 1866-1876.

References

[1] Choat B, Jansen S, Brodribb TJ, et al. Global convergence in the vulnerability of forests to drought. Nature, 2012, 491: 752-755
[2] Prudhomme C, Giuntoli I, Robinson EL, et al. Hydrological droughts in the 21st century, hotspots and uncertainties from a global multimodel ensemble experiment. Proceedings of the National Academy of Sciences of the United States of America, 2014, 111: 3262-3267
[3] Anderegg WRL, Schwalm C, Biondi F, et al. Pervasive drought legacies in forest ecosystems and their implications for carbon cycle models. Science, 2015, 349: 528-532
[4] Liu N, Deng ZJ, Wang HL, et al. Thermal remote sen-sing of plant water stress in natural ecosystems. Forest Ecology and Management, 2020, 476: 118433
[5] Liu LQ, Gao X, Ren CH, et al. Applicability of the crop water stress index based on canopy-air temperature differences for monitoring water status in a cork oak plantation, northern China. Agricultural and Forest Meteorology, 2022, 327: 109226
[6] Ballester C, Jiménez-Bello MA, Castel JR, et al. Usefulness of thermography for plant water stress detection in citrus and persimmon trees. Agricultural and Forest Meteorology, 2013, 168: 120-129
[7] Gontia NK, Tiwari KN. Development of crop water stress index of wheat crop for scheduling irrigation using infrared thermometry. Agricultural Water Management, 2008, 95: 1144-1152
[8] Gautam D, Pagay V. A review of current and potential applications of remote sensing to study the water status of horticultural crops. Agronomy, 2020, 10: 140
[9] Jones HG. Irrigation scheduling: Advantages and pitfalls of plant-based methods. Journal of Experimental Botany, 2004, 55: 2427-2436
[10] García-Tejero IF, Hernández A, Padilla-Díaz CM, et al. Assessing plant water status in a hedgerow olive orchard from thermography at plant level. Agricultural Water Management, 2017, 188: 50-60
[11] Idso SB, Jackson RD, Pinter J, et al. Normalizing the stress-degree-day parameter for environmental variability. Agricultural Meteorology, 1981, 24: 45-55
[12] Jackson RD, Idso SB, Reginato RJ, et al. Canopy temperature as a crop water stress indicator. Water Resources Research, 1981, 17: 1133-1138
[13] Jones HG. Use of infrared thermometry for estimation of stomatal conductance as a possible aid to irrigation scheduling. Agricultural and Forest Meteorology, 1999, 95: 139-149
[14] Maes WH, Steppe K. Estimating evapotranspiration and drought stress with ground-based thermal remote sensing in agriculture: A review. Journal of Experimental Botany, 2012, 63: 4671-4712
[15] Han M, Zhang HH, DeJonge KC, et al. Comparison of three crop water stress index models with sap flow mea-surements in maize. Agricultural Water Management, 2018, 203: 366-375
[16] Payero JO, Irmak S. Variable upper and lower crop water stress index baselines for corn and soybean. Irrigation Science, 2006, 25: 21-32
[17] King BA, Tarkalson DD, Sharma V, et al. Thermal crop water stress index base line temperatures for sugarbeet in arid western U.S. Agricultural Water Management, 2021, 243: 106459
[18] King BA, Shellie KC. Evaluation of neural network mo-deling to predict non-water-stressed leaf temperature in wine grape for calculation of crop water stress index. Agricultural Water Management, 2016, 167: 38-52
[19] King BA, Shellie KC. Wine grape cultivar influence on the performance of models that predict the lower thre-shold canopy temperature of a water stress index. Computers and Electronics in Agriculture, 2018, 145: 122-129
[20] Tong X, Mu YM, Zhang JS, et al. Water stress controls on carbon flux and water use efficiency in a warm-temperate mixed plantation. Journal of Hydrology, 2019, 571: 669-678
[21] 刘震. 我国水土保持情况普查及成果运用. 中国水土保持科学, 2013, 11(2): 1-5
[22] Liu LQ, Xie YC, Gao X, et al. A new threshold-based method for extracting canopy temperature from thermal infrared images of cork oak plantations. Remote Sensing, 2021, 13: 5028
[23] Gardner BR, Nielsen DC, Shock CC. Infrared thermo-metry and the crop water stress index. II. Sampling procedures and interpretation. Journal of Production Agriculture, 1992, 5: 466-475
[24] Gu L, Fuentes JD, Shugart HH, et al. Responses of net ecosystem exchanges of carbon dioxide to changes in cloudiness: Results from two North American deciduous forests. Journal of Geophysical Research: Atmospheres, 1999, 104: 31421-31434
[25] Li ZH, Zhang Q, Li J, et al. Solar-induced chlorophyll fluorescence and its link to canopy photosynthesis in maize from continuous ground measurements. Remote Sensing of Environment, 2020, 236: 111420
[26] Egea G, Padilla-Díaz CM, Martinez-Guanter J, et al. Assessing a crop water stress index derived from aerial thermal imaging and infrared thermometry in super-high density olive orchards. Agricultural Water Management, 2017, 187: 210-221
[27] Bellvert J, Marsal J, Girona J, et al. Airborne thermal imagery to detect the seasonal evolution of crop water status in peach, nectarine and saturn peach orchards. Remote Sensing, 2016, 8: 39
[28] Gonzalez-Dugo V, Zarco-Tejada PJ, Fereres E. Applicability and limitations of using the crop water stress index as an indicator of water deficits in citrus orchards. Agricultural and Forest Meteorology, 2014, 198-199: 94-104
[29] Romero-Trigueros C, Bayona Gambín JM, Nortes Tortosa PA, et al. Determination of crop water stress index by infrared thermometry in grapefruit trees irrigated with saline reclaimed water combined with deficit irrigation. Remote Sensing, 2019, 11: 757
[30] Stockle CO, Dugas WA. Evaluating canopy temperature-based indices for irrigation scheduling. Irrigation Science, 1992, 13: 31-37
[31] Jalali-Farahani HR, Slack DC, Kopec DM, et al. Crop water stress index models for Bermudagrass turf: A comparison. Agronomy Journal, 1993, 85: 1210-1217
[32] Dragoni D, Lakso AN, Piccioni RM. Transpiration of apple trees in a humid climate using heat pulse sap flow gauges calibrated with whole-canopy gas exchange chambers. Agricultural and Forest Meteorology, 2005, 130: 85-94
[33] Gonzalez-Dugo V, Testi L, Villalobos FJ, et al. Empirical validation of the relationship between the crop water stress index and relative transpiration in almond trees. Agricultural and Forest Meteorology, 2020, 292-293: 108128
[34] Grant OM, Tronina L, Jones HG, et al. Exploring thermal imaging variables for the detection of stress responses in grapevine under different irrigation regimes. Journal of Experimental Botany, 2007, 58: 815-825
[35] Stannard DI. Comparison of Penman-Monteith, Shuttleworth-Wallace, and modified Priestley-Taylor evapotranspiration models for wildland vegetation in semiarid rangeland. Water Resources Research, 1993, 29: 1379-1392
[36] 张智韬, 张秋雨, 杨宁, 等. 冬小麦冠层温度对大气温度的时滞效应与影响因素研究. 农业机械学报, 2023, 54(11): 359-368
[37] 刘婧然, 武金坤, 王喆, 等. 棉花叶温与气象条件的关系研究. 节水灌溉, 2013(2): 1-4
[38] Kim Y, Still CJ, Roberts DA, et al. Thermal infrared imaging of conifer leaf temperatures: Comparison to thermocouple measurements and assessment of environmental influences. Agricultural and Forest Meteorology, 2018, 248: 361-371
[39] Leuzinger S, Körner C. Tree species diversity affects canopy leaf temperatures in a mature temperate forest. Agricultural and Forest Meteorology, 2007, 146: 29-37
[40] Yuan WP, Cai WW, Xia JZ, et al. Global comparison of light use efficiency models for simulating terrestrial vegetation gross primary production based on the LaThuile database. Agricultural and Forest Meteorology, 2014, 192-193: 108-120
[41] Liu LQ, Gao X, Cao BH, et al. Comparing different light use efficiency models to estimate the gross primary productivity of a cork oak plantation in Northern China. Remote Sensing, 2022, 14: 5905