Actual water consumption index of horticultural and field crops in Iran: classification into high- and low -water consuming categories

Authors

  • Niaz Ali Ebrahimipak Soil and Water Research Institute, Agricultural Research, Education and Extension Organization (AREEO), Karaj, Iran
  • Azadeh Sedaghat Soil and Water Research Institute, Agricultural Research, Education and Extension Organization (AREEO), Karaj, Iran

Keywords:

Field crops, Horticultural crops, Crop water requirement, Irrigation management, Iran agriculture, Water consumption index

Abstract

Water scarcity is a critical threat to agricultural sustainability in arid and semi-arid regions. Iran, receiving only 240 mm of annual
precipitation on average, faces severe and growing pressure on its water resources, with agriculture accounting for the bulk of
freshwater withdrawals. under such conditions, accurately quantifying the actual water consumption (WRa) of crops is essential
for sustainable water resource management and cropping pattern reform. This study calculated and classified the WRa for 83
field and horticulture crops across Iran, using a 10-year national dataset (2013–2023) and a mean WRa threshold of 600 mm to
distinguish high water-consuming (HWC) from low water-consuming (LWC) crops. Results showed that 44 crops were classified
as HWC and 28 as LWC. Among field crops, sugarcane (Saccharum officinarum; 3,046.8 mm), alfalfa (Medicago sativa; 1,603.9 mm)
and Paddy rice (Oryza sativa; 1,249.0) exhibited the highest WRa, while carrot (255.6 mm) and celery (269.5 mm) were the lowest.
Among horticulture crops, papaya (Carica papaya; 1,387.6 mm) and date palm (Phoenix dactylifera; 1,286.4 mm) exhibited the
highest WRa values, followed by banana (Musa acuminata; 1,217.0 mm) and Sapodilla (Manilkara zapota; 1,132.0 mm), reflecting the
exceptional evaporative demand of tropical and subtropical species cultivated in Iran’s arid regions. Although the average WRa of
HWC horticulture crops (838.1 mm) was lower than that of HWC field crops (1,086.2 mm), the greater number of HWC horticultural
species resulted in a cumulative WRa of 36,877.9 (mm, accounting for 72.3% of the total water use within the HWC category and
representing the single largest contributor to agricultural water consumption in Iran. Overall, HWC crops (44 of 83 studied)
accounted for 80.3% of total agriculture water use. These findings underscore that reforming horticultural cropping patterns,
particularly by restricting tropical and subtropical species with high evaporative demand and promoting low-WRa alternatives, is
essential for sustainable water resource management in Iran’s water-stressed agricultural sector.

Downloads

Download data is not yet available.

References

Ahmed, S. B., Alawad, B. M. H. and Saeed, A. B. 2024. Effect of Irrigation Quantity on Water Use Efficiency of Guar under New Halfa Condition, Sudan. International Journal 9(5): 26–35.

Allen, R. G., Pereira, L. S., Raes, D. and Smith, M. 1998. Crop Evapotranspiration-Guidelines for Computing Crop Water Requirements-FAO Irrigation and Drainage Paper 56. FAO, Rome 300(9): D05109.

Bayisa, G. D., Ayana, M., Mekonnen, B., Hordofa, T. and Dinka, M. O. 2024. Drainage Lysimeter Based Measurement of Water Requirement and Crop Coefficient of Bread Wheat under Semi-Arid Climate of Melkassa, Ethiopia. Heliyon 10(17).

Bekele, T. T. 2025. Potato Production in Ethiopia: Challenges, Opportunities, and Strategies for Sustainable Growth.

Bijlwan, A., Pokhriyal, S., Ranjan, R., Singh, R. K. and Jha, A. 2024. Machine Learning Methods for Estimating Reference Evapotranspiration. Journal of Agrometeorology 26(1): 63–68.

Boser, A., Caylor, K., Larsen, A., Pascolini-Campbell, M., Reager, J. T. and Carleton, T. 2024. Field-Scale Crop Water Consumption Estimates Reveal Potential Water Savings in California Agriculture. Nature Communications 15(1): 2366.

Brendel, O. 2021. The Relationship between Plant Growth and Water Consumption: A History from the Classical Four Elements to Modern Stable Isotopes. Annals of Forest Science 78: 47.

Chukalla, A. D., Mekonnen, M. M., Gunathilake, D., Wolkeba, F. T., Gunasekara, B. and Vanham, D. 2025. Global Spatially Explicit Crop Water Consumption Shows an Overall Increase of 9% for 46 Agricultural Crops from 2010 to 2020. Nature Food 6(10): 983–994.

Daccache, A., D'Agostino, D., Lamaddalena, N. and El Chami, D. 2016. A Decision Tool for Sustainable Agricultural Policies: The Case of Water Saving Scenarios for Apulia Region (Southern Italy). Water Policy 18(1): 126–142.

Ebrahimipak, N. A. and Sedaghat, A. 2025. An Analysis on Evaluation of Virtual Water Index of Horticultural and Field Crops Grown in Iran. International Journal of Innovative Horticulture14(2): 151–161.

Ebrahimipak, N., Sedaghat, A. and Tafteh, A. 2026. Spatial Analysis of Water Requirements and Water‐Use Efficiency in Wheat Cultivation across Iran Using Data From the Water Requirement System. Irrigation and Drainage.

Fereres, E. and Soriano, M. A. 2007. Deficit Irrigation for Reducing Agricultural Water Use. Journal of Experimental Botany 58(2): 147–159.

Fereres, E., Goldhamer, D. A. and Parsons, L. R. 2003. Irrigation Water Management of Horticultural Crops. HortScience 38(5): 1036–1042.

Gil-Marín, J. A., Zermeño-González, A., Córdova-Rodríguez, M. X., Ramírez-Rodríguez, H., Melendres-Alvarez, A. I., Moreno, L. S. and Khamkure, S. 2025. Evapotranspiration and the Crop Coefficients of Black Bean (Phaseolus vulgaris L.) with Weighing Lysimeters. Asian Journal of Agriculture 9: 349–357.

Hao, L., Su, X. and Singh, V. P. 2018. Cropping Pattern Optimization Considering Uncertainty of Water Availability and Water Saving Potential. International Journal of Agricultural and Biological Engineering 11(1): 178–186.

Hatfield, J. L. and Dold, C. 2019. Water-Use Efficiency: Advances and Challenges in a Changing Climate. Frontiers in Plant Science 10: 103.

Ichwan, N., Meliala, F.S., Ezra, M.F., Nainggolan, M.B., Nasution, D.L.S. and Daulay, S.B. 2022. Water Consumption, Growth, Yield and Water Productivity for Pepper Plant. IOP Conference Series: Earth and Environmental Science 977(1): 012076.

Karandish, F. and Hoekstra, A. Y. 2017. Informing National Food and Water Security Policy through Water Footprint Assessment: The Case of Iran. Water 9(11): 831.

Karandish, F., Hoekstra, A. Y. and Hogeboom, R. J. 2018. Groundwater Saving and Quality Improvement by Reducing Water Footprints of Crops to Benchmarks Levels. Advances in Water Resources 121: 480–491.

Katerji, N. and Mastrorilli, M. 2014. Water Use Efficiency of Cultivated Crops. eLS.

Kebede, N., Ayana, M. and Mekonnen, B. 2025. Quantification of Onion (Allium cepa L.) Evapotranspiration and Crop Coefficient via Weighable Lysimeter under Semi-Arid Climate of Melkasa, Ethiopia. Heliyon 11(4).

Keyser-Gibson, A., Nackley, L., Sun, Y., Sisneroz, J., Haver, D., Contreras, R., Schuch, U.K., Oki, L. and Kim, S.H. 2025. Plasticity in Plant Hydraulic Traits: An Evaluation of a Common-Taxa Experiment Across a Climatic Gradient in the Western US. Plants, People, Planet.

Khajavigodellou, Y., Qi, J., Soltani, M., Zarrin, Z., Karimi, H. and Bakhshianlamouki, E. 2026. Optimization of Agricultural Systems Under Water-Energy-Food Nexus: A Framework for the Urmia Lake Basin. Sustainability 18(2): 843.

Khorsandi, M., Omidi, T. and van Oel, P. 2023. Water-Related Limits to Growth for Agriculture in Iran. Heliyon 9(5).

Lamsal, G. and Marston, L. T. 2025. Monthly Crop Water Consumption of Irrigated Crops in the United States from 1981 to 2019. Water Resources Research 61(2): e2024WR038334.

Li, G., Ma, D., Zhao, C. and Li, H. 2023. The Effect of the Comprehensive Reform of Agricultural Water Prices on Farmers’ Planting Structure in the Oasis–Desert Transition Zone—A Case Study of the Heihe River Basin. International Journal of Environmental Research and Public Health 20(6): 4915.

Mirzaei, A., Saghafian, B., Mirchi, A. and Madani, K. 2019. The Groundwater‒Energy‒Food Nexus in Iran’s Agricultural Sector: Implications for Water Security. Water 11(9): 1835.

Negash, T. W., Dirirsa Bayisa, G., Tefera, A. T., Tezera Bizuneh, K., Dinku, A. G., Awulachew, T. W. and Ashemi Bikela, G. 2023. Evapotranspiration and Crop Coefficient of Sorghum (Sorghum bicolor L.) at Melkassa Farmland, Semi-Arid Area of Ethiopia. Air, Soil and Water Research 16: 11786221231184206.

Negash, T. W., Tefera, A. T. and Bayisa, G. D. 2024. Maize (Zea mays L., 1753.) Evapotranspiration and Crop Coefficient in Semi-Arid Region of Ethiopia. Italian Journal of Agrometeorology 2: 55–63.

Preite, L., Solari, F. and Vignali, G. 2023. Technologies to Optimize the Water Consumption in Agriculture: A Systematic Review. Sustainability 15(7): 5975.

Tercek, M. T., Thoma, D., Gross, J. E., Sherrill, K., Kagone, S. and Senay, G. 2021. Historical Changes in Plant Water Use and Need in the Continental United States. PLOS ONE 16(9): e0256586.

Wong, A. J., Jin, Y., Medellín‐Azuara, J., Paw U, K. T., Kent, E. R., Clay, J. M. and Hook, S. J. 2021. Multiscale Assessment of Agricultural Consumptive Water Use in California's Central Valley. Water Resources Research 57(9): e2020WR028876.

Zamani, A., Rostamian, R. and Norouzi, G. 2024. Comparative Assessment of Environmental Impacts and Water Scarcity Footprint of Horticultural Crops in Iran. Environmental Research 257: 119082.

Zou, M., Kang, S., Niu, J. and Lu, H. 2018. A New Technique to Estimate Regional Irrigation Water Demand and Driving Factor Effects Using an Improved SWAT Model with LMDI Factor Decomposition in an Arid Basin. Journal of Cleaner Production 185: 814–828.

Downloads

Published

2026-06-21

How to Cite

Ebrahimipak , N. A. ., & Sedaghat, A. . (2026). Actual water consumption index of horticultural and field crops in Iran: classification into high- and low -water consuming categories. Current Horticulture, 14(2), 58–67. Retrieved from https://www.currenthorticulture.com/index.php/CURHOR/article/view/365