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Uniyal S, Purohit S, Chaurasia K, Rao SS, Amminedu E. 2022. Quantification of carbon sequestration by urban forest using Landsat 8 OLI and machine learning algorithms in Jodhpur, India. Urban Forestry & Urban Greening 67:127445

Yao N, Konijnendijk van den Bosch CC, Yang J, Devisscher T, Wirtz Z, et al. 2019. Beijing's 50 million new urban trees: Strategic governance for large-scale urban afforestation. Urban Forestry & Urban Greening 44:126392

Choat B, Jansen S, Brodribb TJ, Cochard H, Delzon S, et al. 2012. Global convergence in the vulnerability of forests to drought. Nature 491:752−755

Asner GP, Brodrick PG, Anderson CB, Vaughn N, Knapp DE, et al. 2016. Progressive forest canopy water loss during the 2012–2015 California drought. Proceedings of the National Academy of Sciences of the United States of America 113(2):E249−E255

Goulden ML, Bales RC. 2019. California forest die-off linked to multi-year deep soil drying in 2012–2015 drought. Nature Geoscience 12(8):632−637

Vicente-Serrano SM, Gouveia C, Camarero JJ, Beguería S, Trigo R, et al. 2013. Response of vegetation to drought time-scales across global land biomes. Proceedings of the National Academy of Sciences of the United States of America 110(1):52−57

Huang X, Hao L, Sun G, Yang ZL, Li W, et al. 2022. Urbanization aggravates effects of global warming on local atmospheric drying. Geophysical Research Letters 49(2):e2021GL095709

Sjöman H, Hirons AD, Bassuk NL. 2015. Urban forest resilience through tree selection—variation in drought tolerance in Acer. Urban Forestry & Urban Greening 14(4):858−865

Cui J, Chen A, Huntingford C, Piao S. 2024. Integrating ecosystem water demands into drought monitoring and assessment under climate change. Nature Water 2(3):215−218

Jones HG. 2004. Irrigation scheduling: advantages and pitfalls of plant-based methods. Journal of Experimental Botany 55(407):2427−36

Ballester C, Jiménez-Bello MA, Castel JR, Intrigliolo DS. 2013. Usefulness of thermography for plant water stress detection in citrus and persimmon trees. Agricultural and Forest Meteorology 168:120−129

Gontia NK, Tiwari KN. 2008. Development of crop water stress index of wheat crop for scheduling irrigation using infrared thermometry. Agricultural Water Management 95(10):1144−1152

Shi TT, Guan DX, Wu JB, Wang AZ, Jin CJ, et al. 2008. Comparison of methods for estimating evapotranspiration rate of dry forest canopy: eddy covariance, Bowen ratio energy balance, and penman-monteith equation. Journal of Geophysical Research 113(D19):2008JD010174

Diffenbaugh NS, Swain DL, Touma D. 2015. Anthropogenic warming has increased drought risk in California. Proceedings of the National Academy of Sciences of the United States of America 112(13):3931−3936

Wang S, Fu B, Wei F, Piao S, Maestre FT, et al. 2023. Drylands contribute disproportionately to observed global productivity increases. Science Bulletin 68(2):224−232

Agam N, Cohen Y, Alchanatis V, Ben-Gal A. 2013. How sensitive is the CWSI to changes in solar radiation? International Journal of Remote Sensing 34(17):6109−6120

Katimbo A, Rudnick DR, DeJonge KC, Lo TH, Qiao X, et al. 2022. Crop water stress index computation approaches and their sensitivity to soil water dynamics. Agricultural Water Management 266:107575

Idso SB, Jackson RD, Pinter PJ, Reginato RJ, Hatfield JL. 1981. Normalizing the stress-degree-day parameter for environmental variability. Agricultural Meteorology 24:45−55

Jackson RD, Idso SB, Reginato RJ, Pinter PJ Jr. 1981. Canopy temperature as a crop water stress indicator. Water Resources Research 17(4):1133−1138

Jones HG. 1999. Use of thermography for quantitative studies of spatial and temporal variation of stomatal conductance over leaf surfaces. Plant, Cell & Environment 22(9):1043−1055

Sánchez-Piñero M, Martín-Palomo MJ, Andreu L, Moriana A, Corell M. 2022. Evaluation of a simplified methodology to estimate the CWSI in olive orchards. Agricultural Water Management 269:107729

Zhang L, Zhang H, Zhu Q, Niu Y. 2023. Further investigating the performance of crop water stress index for maize from baseline fluctuation, effects of environmental factors, and variation of critical value. Agricultural Water Management 285:108349

Zhang Q, Yang X, Liu C, Yang N, Yu G, et al. 2024. Monitoring soil moisture in winter wheat with crop water stress index based on canopy-air temperature time lag effect. International Journal of Biometeorology 68(4):647−659

Liu P, Tong X, Meng P, Zhang J, Li J, et al. 2022. b. Biophysical controls on water use efficiency of six plantations under different sky conditions. Agricultural and Forest Meteorology 320:108938

Pan SA. 2022. Variation of hydraulic conductivity at altitude and related morphological and physiological characteristics of Faxon fir. Thesis (in Chinese). Beijing Forestry University, China

Maes WH, Steppe K. 2012. Estimating evapotranspiration and drought stress with ground-based thermal remote sensing in agriculture: a review. Journal of Experimental Botany 63(13):4671−4712

Chen Q, Liu Y, Fu X, Hou Y, Hui J, et al. 2025. Water-use strategies of Chinese fir to simulated precipitation change in a subtropical region. Forestry: An International Journal of Forest Research 00:cpaf041

Wang X, Guo H, Bao YMD, Zhou GY, Chen YH, et al. 2025. Damaged characteristics and influencing factors of cunninghamia lanceolata mixed plantations in subtropics under extreme drought conditions. Scientia Silvae Sinica 61(5):12−22 (in Chinese)

Liu L, Xie Y, Gao X, Cheng X, Huang H, et al. 2021. A new Threshold-Based method for extracting canopy temperature from thermal infrared images of Cork oak plantations. Remote Sensing 13(24):5028

Liu L, Gao X, Ren C, Cheng X, Zhou Y, et al. 2022. 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 327:109226

Zhou Y, Zhang J, Yin C, Huang H, Sun S, et al. 2022. Empirical analysis of the influences of meteorological factors on the interannual variations in carbon fluxes of a Quercus variabilis plantation. Agricultural and Forest Meteorology 326:109190

Gu LH, Fuentes JD, Shugart HH, Staebler RM, Black TA. 1999. Responses of net ecosystem exchanges of carbon dioxide to changes in cloudiness: Results from two North American deciduous forests. Journal Of Geophysical Research-atmospheres 104(D24):31421−31434

Li Z, Zhang Q, Li J, Yang X, Wu Y, et al. 2020. Solar-induced chlorophyll fluorescence and its link to canopy photosynthesis in maize from continuous ground measurements. Remote Sensing of Environment 236:111420

Liu N, Deng Z, Wang H, Luo Z, Gutiérrez-Jurado HA, et al. 2020. Thermal remote sensing of plant water stress in natural ecosystems. Forest Ecology and Management 476:118433

Tong X, Mu Y, Zhang J, Meng P, Li J. 2019. Water stress controls on carbon flux and water use efficiency in a warm-temperate mixed plantation. Journal of Hydrology 571:669−678

Thom AS, Oliver HR. 1977. On Penman's equation for estimating regional evaporation. Quarterly Journal of the Royal Meteorological Society 103(436):345−357

Jackson RD, Kustas WP, Choudhury BJ. 1988. A reexamination of the crop water stress index. Irrigation science 9(4):309−317

Monteith JL, Reifsnyder WE. 1974. Principles of Environmental Physics. Physics Today 27(3):51−52

García-Tejero IF, Costa JM, Egipto R, Durán-Zuazo VH, Lima RSN, et al. 2016. Thermal data to monitor crop-water status in irrigated Mediterranean viticulture. Agricultural Water Management 176:80−90

Bian J, Zhang Z, Chen J, Chen H, Cui C, et al. 2019. Simplified evaluation of cotton water stress using high resolution unmanned aerial vehicle thermal imagery. Remote Sensing 11(3):267

Jarvis PG, McNaughton KG. 1986. Stomatal control of transpiration: scaling up from leaf to region. Advances in Ecological Research 15:1−49

Rigden AJ, Mueller ND, Holbrook NM, Pillai N, Huybers P. 2020. Combined influence of soil moisture and atmospheric evaporative demand is important for accurately predicting US maize yields. Nature Food 1(2):127−133

Wilson TG, Kustas WP, Alfieri JG, Anderson MC, Gao F, et al. 2020. Relationships between soil water content, evapotranspiration, and irrigation measurements in a California drip-irrigated Pinot noir vineyard. Agricultural Water Management 237:106186

Deng C, Wu ZX, Tan ZH, Liao LG, Cui YB, et al. 2020. Variations of canopy temperature in a rubber plantation in Western Hainan Island and their relations with micrometeorological factors. Chinese Journal of Tropical Crops 41(7):1490−1497 (in Chinese)

Kim Y, Still CJ, Roberts DA, Goulden ML. 2018. Thermal infrared imaging of conifer leaf temperatures: Comparison to thermocouple measurements and assessment of environmental influences. Agricultural and Forest Meteorology 248:361−371

Gates DM. 1980. Biophysical Ecology. New York: Springer-Verleg. pp. 15

Kim Y, Still CJ, Hanson CV, Kwon H, Greer BT, et al. 2016. Canopy skin temperature variations in relation to climate, soil temperature, and carbon flux at a ponderosa pine forest in central Oregon. Agricultural and Forest Meteorology 226−227:161−173

Egea G, Padilla-Díaz CM, Martinez-Guanter J, Fernández JE, Pérez-Ruiz M. 2017. Assessing a crop water stress index derived from aerial thermal imaging and infrared thermometry in super-high density olive orchards. Agricultural Water Management 187:210−221

Romero-Trigueros C, Bayona Gambín JM, Nortes Tortosa PA, Alarcón Cabañero JJ, Nicolás Nicolás E. 2019. Determination of crop water stress index by infrared thermometry in grapefruit trees irrigated with saline reclaimed water combined with deficit irrigation. Remote Sensing 11(7):757−780

Testi L, Goldhamer DA, Iniesta F, Salinas M. 2008. Crop water stress index is a sensitive water stress indicator in pistachio trees. Irrigation Science 26(5):395−405

Bellvert J, Zarco-Tejada PJ, Girona J, Fereres E. 2014. Mapping crop water stress index in a 'Pinot-noir' vineyard: comparing ground measurements with thermal remote sensing imagery from an unmanned aerial vehicle. Precision Agriculture 15(4):361−376

Osroosh Y, Peters RT, Campbell CS. 2016. Daylight crop water stress index for continuous monitoring of water status in apple trees. Irrigation Science 34(3):209−219

Alghory A, Yazar A. 2019. Evaluation of crop water stress index and leaf water potential for deficit irrigation management of sprinkler-irrigated wheat. Irrigation Science 37(1):61−77

Anda A, Simon B, Soós G, Teixeira da Silva JA, Kucserka T. 2019. Crop-water relation and production of two soybean varieties under different water supplies. Theoretical and Applied Climatology 137(1-2):1515−1528

Bellvert J, Marsal J, Girona J, Gonzalez-Dugo V, Fereres E, et al. 2016. Airborne thermal imagery to detect the seasonal evolution of crop water status in peach, nectarine and saturn peach orchards. Remote Sensing 8(1):39

Berni JAJ, Zarco-Tejada PJ, Sepulcre-Cantó G, Fereres E, Villalobos F. 2009. Mapping canopy conductance and CWSI in olive orchards using high resolution thermal remote sensing imagery. Remote Sensing of Environment 113(11):2380−2388

Gonzalez-Dugo V, Zarco-Tejada PJ. 2024. Assessing the impact of measurement errors in the calculation of CWSI for characterizing the water status of several crop species. Irrigation Science 42(3):431−443

Khorsandi A, Hemmat A, Ahmad Mireei S, Amirfattahi R, Ehsanzadeh P. 2018. Plant temperature-based indices using infrared thermography for detecting water status in sesame under greenhouse conditions. Agricultural Water Management 204:222−233

Ben-Gal A, Agam N, Alchanatis V, Cohen Y, Yermiyahu U, et al. 2009. Evaluating water stress in irrigated olives: correlation of soil water status, tree water status, and thermal imagery. Irrigation Science 27(5):367−376

Han M, Zhang H, DeJonge KC, Comas LH, Gleason S. 2018. Comparison of three crop water stress index models with sap flow measurements in maize. Agricultural Water Management 203:366−375