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Thermal data to monitor crop-water status in irrigated Mediterranean viticulture

Author

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  • García-Tejero, I.F.
  • Costa, J.M.
  • Egipto, R.
  • Durán-Zuazo, V.H.
  • Lima, R.S.N.
  • Lopes, C.M.
  • Chaves, M.M.

Abstract

Canopy temperature (TC) can be a robust indicator of grapevine water status. However, the assessment of TC by thermography in field conditions requires optimization, especially under variable environmental conditions (daily and seasonal) just like it occurs in Mediterranean areas. Besides, simplicity and robustness should be the basis of a wider use of thermography in field conditions. Therefore the comparison of simpler and more complex approaches in terms of thermal indicators is wise to test. Our major aims were: i) to assess the performance of four common thermal indicators (canopy temperature − TC, Crop Water Stress Index − CWSI, index of relative stomatal conductance − IG, and the difference between TC and the surrounding air − ΔTcanopy-air) to support irrigation decisions ii) to optimize the timing of thermal measurements for different genotypes and iii) to obtain mathematical functions to estimate leaf gas exchange parameters on the basis of thermal data. The trial was conducted in the summer of 2013, in south Portugal. Two V. vinifera red varieties, Touriga Nacional and Aragonez (syn. Tempranillo) were tested. Vines were subjected to two irrigation regimes: i) sustained-deficit irrigation (based on the farm’s schedule − control) and ii) regulated-deficit irrigation (∼50% of the control). We found that measurements done between 11:00 and 17:00h provide the most significant correlations between TC, CWSI and IG and leaf stomatal conductance and net photosynthesis for both genotypes. Different linear mathematical functions were obtained to estimate leaf gas exchange based on the best performing thermal indicators under field conditions. Our results emphasize the value of TC as a relevant explanatory variable of vine’s physiological status, in spite of being a simpler and non-normalized thermal indicator. The potential relevance of TC for grapevine modelling and phenotyping is also discussed.

Suggested Citation

  • García-Tejero, I.F. & Costa, J.M. & Egipto, R. & Durán-Zuazo, V.H. & Lima, R.S.N. & Lopes, C.M. & Chaves, M.M., 2016. "Thermal data to monitor crop-water status in irrigated Mediterranean viticulture," Agricultural Water Management, Elsevier, vol. 176(C), pages 80-90.
    • Handle: RePEc:eee:agiwat:v:176:y:2016:i:c:p:80-90
    DOI: 10.1016/j.agwat.2016.05.008
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    References listed on IDEAS

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    1. Costa, J.M. & Vaz, M. & Escalona, J. & Egipto, R. & Lopes, C. & Medrano, H. & Chaves, M.M., 2016. "Modern viticulture in southern Europe: Vulnerabilities and strategies for adaptation to water scarcity," Agricultural Water Management, Elsevier, vol. 164(P1), pages 5-18.
    2. Bota, J. & Tomás, M. & Flexas, J. & Medrano, H. & Escalona, J.M., 2016. "Differences among grapevine cultivars in their stomatal behavior and water use efficiency under progressive water stress," Agricultural Water Management, Elsevier, vol. 164(P1), pages 91-99.
    3. Pou, Alícia & Diago, Maria P. & Medrano, Hipólito & Baluja, Javier & Tardaguila, Javier, 2014. "Validation of thermal indices for water status identification in grapevine," Agricultural Water Management, Elsevier, vol. 134(C), pages 60-72.
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    1. Pappalardo, S. & Consoli, S. & Longo-Minnolo, G. & Vanella, D. & Longo, D. & Guarrera, S. & D’Emilio, A. & Ramírez-Cuesta, J.M., 2023. "Performance evaluation of a low-cost thermal camera for citrus water status estimation," Agricultural Water Management, Elsevier, vol. 288(C).
    2. Ezenne, G.I. & Jupp, Louise & Mantel, S.K. & Tanner, J.L., 2019. "Current and potential capabilities of UAS for crop water productivity in precision agriculture," Agricultural Water Management, Elsevier, vol. 218(C), pages 158-164.
    3. Poirier-Pocovi, Magalie & Volder, Astrid & Bailey, Brian N., 2020. "Modeling of reference temperatures for calculating crop water stress indices from infrared thermography," Agricultural Water Management, Elsevier, vol. 233(C).
    4. Costa, J.M. & Egipto, R. & Sánchez-Virosta, A. & Lopes, C.M. & Chaves, M.M., 2019. "Canopy and soil thermal patterns to support water and heat stress management in vineyards," Agricultural Water Management, Elsevier, vol. 216(C), pages 484-496.
    5. Apolo-Apolo, O.E. & Martínez-Guanter, J. & Pérez-Ruiz, M. & Egea, G., 2020. "Design and assessment of new artificial reference surfaces for real time monitoring of crop water stress index in maize," Agricultural Water Management, Elsevier, vol. 240(C).
    6. García-Tejero, I.F. & Hernández, A. & Padilla-Díaz, C.M. & Diaz-Espejo, A. & Fernández, J.E, 2017. "Assessing plant water status in a hedgerow olive orchard from thermography at plant level," Agricultural Water Management, Elsevier, vol. 188(C), pages 50-60.
    7. García-Tejero, I.F. & Rubio, A.E. & Viñuela, I. & Hernández, A & Gutiérrez-Gordillo, S & Rodríguez-Pleguezuelo, C.R. & Durán-Zuazo, V.H., 2018. "Thermal imaging at plant level to assess the crop-water status in almond trees (cv. Guara) under deficit irrigation strategies," Agricultural Water Management, Elsevier, vol. 208(C), pages 176-186.

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