Hostname: page-component-586b7cd67f-l7hp2 Total loading time: 0 Render date: 2024-11-28T15:22:23.197Z Has data issue: false hasContentIssue false
  • English
  • Français

THE WATER RELATIONS AND IRRIGATION REQUIREMENTS OF THE DATE PALM (Phoenix dactylifera L.): A REVIEW

Published online by Cambridge University Press:  19 November 2012

M. K. V. CARR
M. K. V. CARR*
Affiliation:
Emeritus Professor, School of Applied Sciences, Cranfield University, Cranfield, Bedfordshire, MK43 0AL, UK
*
Corresponding author. Email: [email protected]. Contact address: Pear Tree Cottage, Frog Lane, Ilmington, Shipston on Stour, Warwickshire, CV36 4LQ, UK.
Get access Rights & Permissions [Opens in a new window]

Summary

Date palm is a crop suited to hot, arid regions. It originated in Mesopotamia and the centres of production are in West Asia and North Africa. Despite its regional and international importance, and its dependence on irrigation or a shallow water table for survival, relatively little research has been published on the water relations and irrigation need of date palm. Following early work in California, the majority of the recent research reported in the literature has been conducted in Saudi Arabia and Tunisia. The date palm has a terminal crown of 100–120 leaves. At the base of each leaf is an axillary bud, most of which develop in the winter as flower buds. It takes 150–200 days from pollination to fruit maturity. Stomata occur on both leaf surfaces. Different techniques have been used to measure the water use of date palm, including micrometeorological and sap flow methods. In Syria, mean actual evapotranspiration rates varied between 0.5 mm d−1 (winter) and 3.5 mm d−1 (summer), in Saudi Arabia from 2–3 to 8–11 mm d−1 depending on location and in Jordan from 2 to 8–10 mm d−1 respectively. In Tunisia, there was some (limited) evidence of stomatal control of transpiration rates (seasonal range 0.5 to 3.5 mm d−1) when temperatures exceeded 32 °C. Experimentally determined values of the crop coefficient were inconsistent, varying from 0.6–0.7 to 1.18. In the vicinity of an oasis, advection may increase potential water use substantially above that of a reference crop. In the absence of a shallow water table, roots can extract water from soil depths greater than 2 m. There is little published information on the water productivity of date palm. A target benchmark figure is probably about 1.3-kg fresh fruit m−3 of irrigation water applied. Under controlled conditions, phenotypes differed in their responses to water stress. The date palm is traditionally considered to be relatively salt-tolerant, with a threshold electrical conductivity value for the saturated soil extract of 4.0 dS m−1, but recent evidence from Israel suggests that this view may be mistaken. Since early times, flood irrigation has been used to irrigate date palm and it is still probably the most common method in many countries. Since the 1980s, farmers have been encouraged by governments to use localised irrigation methods (e.g. micro-sprinklers, drip and bubbler) as a means of saving water. Since water is a scarce resource in the West Asia and North Africa region, research should focus on developing ways to improve the water productivity of this high value crop.

Type
Review Paper
Information
Experimental Agriculture , Volume 49 , Issue 1 , January 2013 , pp. 91 - 113
Copyright
Copyright © Cambridge University Press 2012

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

Abdul-Baki, A. A. and Aslan, S. (2004). Management of soil and water in date palm orchards in Coachella Valley, California. Paper Presented at ICARDA Regional Meeting on Date Palm Development in the Arabian Peninsular, Abu Dhabi.Google Scholar
Ahmed, T. F., Hashmi, H. N. and Ghumman, A. R. (2011). Performance assessment of subsurface drip irrigation system using pipes of varying flexibility. Mehran University Research Journal of Engineering and Technology 30 (3):361370.Google Scholar
Ahmed, T. F., Hashmi, H. N., Ghumman, A. R. and Sheikh, A. A. (2012). Performance assessment of surface and subsurface drip irrigation system for date palm fruit trees. African Journal of Agricultural Research 7 (10):15421549.Google Scholar
Al-Amoud, A. I. (2008). Performance of bubbler irrigation system as compared to trickle for large size date palm tree farm. Paper Presented at the Canadian Society for Bioengineering Annual Conference, Vancouver, British Columbia, No. CSBE 08-172.Google Scholar
Al-Amoud, A. I. (2010). Subsurface drip irrigation for date palm trees to conserve water. Acta Horticulturae (ISHS) 882:103114.Google Scholar
Al-Amoud, A. I., Bacha, M. A. and Al-Darby, A. M. (2000). Seasonal water use of date palm in the central region of Saudi Arabia. Agricultural Engineering Journal 9 (2):5162.Google Scholar
Al-Amoud, A. I., Mohammad, F. S., Saad, A. A. and Alabdulkader, A. M. (2012). Reference evapotranspiration and date palm water use in the Kingdom of Saudi Arabia. International Research Journal of Agricultural Science and Soil Science 2 (4):156169.Google Scholar
Alazba, A. (2004). Estimating palm water requirements using Penman-Monteith mathematical model. Journal of the King Saud University – Agricultural Sciences 16 (2):137152.Google Scholar
Aldrich, W. W. (1942). Some effects of soil moisture deficiency upon Deglet Noor fruit. Date Growers’ Institute 19:710.Google Scholar
Aldrich, W. W., Crawford, C. L., Nixon, R. W. and Reuther, W. (1942). Some factors affecting rate of date leaf elongation. American Society for Horticultural Science Proceedings 41:7784.Google Scholar
Alhammadi, M. S. and Kurup, S. S. (2012). Impact of salinity stress on date palm (Phoenix dactylifera L.) – a review, Chapter 9. In Crop Production Technologies, 169178 (Eds. Sharma, P. and Abrol, V.). Rijeka, Croatia: InTech (open access).Google Scholar
Al-Khateeb, S. A., Al-Khateeb, A. A. and Ali-Dinar, H. M. (2003). Photosynthesis Efficiency of Date Palm Varieties Grown in Saudi Arabia. Final Technical Report (Project 2001), King Faisal University, Saudi Arabia.Google Scholar
Allen, R. G., Pereira, L. S., Raes, D. and Smith, M. (1998). Crop evapotranspiration: guidelines for computing crop water requirements. Food and Agricultural Organisation of the United Nations, Irrigation and Drainage Paper 56, Rome, Italy.Google Scholar
Al-Obeed, R. S. (2005). Rooting of aerial offshoots of four date palm (Phoenix dactylifera L.) cultivars by air layering method using polyethylene bags. Pakistan Journal of Biological Sciences 8 (7):978981.Google Scholar
Al-Saikhan, M. S. (2008). Effect of fruit thinning practices on fruit yield and quality of Ruzeiz date palm cultivar (Phoenix dactylifera L.) in Al-Ahsa, Saudi Arabia. Asian Journal of Plant Sciences 7 (1):105108.Google Scholar
Alshuaibi, A. (2011). The econometrics of investment in date production in Saudi Arabia. The International Journal of Applied Economics and Finance 5 (3):177184.Google Scholar
Al-Whaibi, M. H. (1988). Leaf CO2 assimilation and conductance of two date palm cultivars. Date Palm Journal 6 (2):355 (abstract only).Google Scholar
Ayers, R. S. and Westcot, D. W. (1985). Water quality for agriculture. FAO Irrigation and Drainage Paper 29, Rome, Italy.Google Scholar
Barreveld, W. H. (1993). Introduction. In Date Palm Products, FAO Agricultural Services Bulletin No. 101. Rome, Italy: FAO.Google Scholar
Ben Aïssa, I., Bouarfa, S. and Perrier, A. (2009). Utilisation de la mesure thermique du flux de sève pour l'évlauation de la transpiration d'un plmier dattier. In Economies d'Eau en Systèmes Irrigués au Maghreb (Eds. Hartani, T., Douaoui, A. and Kuper, M.). Actes du quatrième atelier régional du projet Sirma, Mostaganem, Algéria, May 2008. Montpellier, France: CIRAD.Google Scholar
Ben Aïssa, I., Bouksila, F., Bahri, A., Bouarfa, S., Chaumont, C. and Hichri, W. (2004). Gestion de l'eau et des sels au sein d'une oasis du Sud Tunisien. In Projet INCO-WADEMED, Actes du Seminaire Modernisation de l'Agriculture Irriguée, Rabat. Available at: http://hal.archives-ouvertes.fr/docs/00/18/81/72/PDF/II_BenAissa.pdf (accessed 4 February 2012).Google Scholar
Bouhoun, M. D., Marlet, S., Brinis, L., Saker, M. L., Rabier, J. and Côte, M. (2011). A survey of the combined effects of water logging and salinity on fruit yield in the date palm groves of the Wargla basin. Algeria. Fruits 66 (1):1124.CrossRefGoogle Scholar
Broschat, T. K. (1998). Root and shoot growth patterns in four palm species and their relationships with air and soil temperatures. HortScience 33 (6):995998.Google Scholar
Brunel, J.-P., Ihab, J., Droubi, A. M. and Samaan, S. (2006). Energy budget and actual evapotranspiration of an arid oasis ecosystem: Palmyra (Syria). Agricultural Water Management 84:213220.CrossRefGoogle Scholar
Carr, M. K. V. (2011a). The water relations and irrigation requirements of coconut (Cocos nucifera L.): a review. Experimental Agriculture 47:2751.Google Scholar
Carr, M. K. V. (2011b). The water relations and irrigation requirements of oil palm (Elaeis guineensis): a review. Experimental Agriculture 47:629652.CrossRefGoogle Scholar
Carr, M. K. V. (2012). Advances in Irrigation Agronomy: Plantation Crops. Cambridge, UK: Cambridge University Press, 360 pp.CrossRefGoogle Scholar
Chao, C. T. and Krueger, R. R. (2007). The date palm (Phoenix dactylifera L.): overview of biology, uses and cultivation. HortScience 42:10771082.Google Scholar
Cohen, Y., Alchanatis, V., Prigojin, A., Levi, A., Soroker, V. and Cohen, Y. (2012). Use of aerial thermal imaging to estimate water status of palm trees. Precision Agriculture 13:123140 (published online 27 May 2011).Google Scholar
Cohen, Y., Freeman, S., Zveibil, A., Zvi, R. B., Nakache, V., Biton, S. and Soroker, V. (2010). Re-evaluation of factors affecting bunch drop in date palm. HortScience 45 (6):887893 (abstract only seen).Google Scholar
El Hadrami, A., Daayf, F. and El Hadrami, I. (2011). Date palm genetics and breeding. In Date Palm Biotechnology, 479512 (Eds Jain, S. M., Al-Khayri, J. M. and Johnson, D. V.). Dordrecht, Netherlands: Springer.Google Scholar
Elshibli, S. (2009). Genetc Diversity and Adaptation of Date Palm (Phoenix dactylifera L.). Thesis, University of Helsinki, Finland.Google Scholar
Elshibli, S. (2010). Biodiversity in date palm (Phoenix dactylifera L.). Available at: http://www.sarab.fi/file/marhaba/2010/m10-s58-71n.pdf (accessed November 2011).Google Scholar
Erskine, W., Moustafa, A. T., Osman, A. E., Lashine, Z., Nejatian, A., Badawi, T. and Ragy, S. M. (2005). Date palm in the GCC countries of the Arabian Peninsular. Available at: http://www.icarda.org/aprp/datepalm/introduction/intro-body.htm (accessed October 2011).Google Scholar
FAO (2008). Irrigated date palm production in the Near East, Chapter 1. In Proceedings of Workshop on Irrigation of Date Palm and Associated Crops 2007, Food and Agriculture Organization of the United Nations, Cairo, Egypt, 115.Google Scholar
FAOSTAT (2012). http://faostat.fao.org/site/339/default.aspx (accessed March 2012).Google Scholar
Furr, J. R. and Armstrong, W. W. (1956). The seasonal use of water by Khadrawy date palms. Date Growers’ Institute Report 23:57.Google Scholar
Furr, J. R. and Armstrong, W. W. Jr (1962). A test of mature Halawy and Medjool date palms for salt tolerance. Date Grower's Institute Report 39:1113.Google Scholar
Furr, J. R., Currlin, E. C., Hilgeman, R. H. and Reuther, W. (1951). An irrigation and fertilization experiment with Deglet Noor dates. Date Growers’ Institute Report 28:1720.Google Scholar
Furr, J. R. and Ream, , , C. L. (1968). Salinity effects on growth and salt uptake of seedlings of the date, Phoenix dactylifera L. Proceedings of the American Society for Horticultural Science 92:268273.Google Scholar
Furr, J. R., Ream, C. L. and Ballard, A. L. (1966). Growth of young date palms in relation to soil salinity and chloride content of the Pinnae. Date Growers’ Institute Report 43:48.Google Scholar
Ghazouani, W., Marlet, S., Mekki, I., Harrington, L. W. and Vidal, A. (2012). Farmers’ practices and community management of irrigation: why do they not match in Fatnassa oasis? Irrigation and Drainage 61:3951.Google Scholar
Ghazouani, W., Marlet, S., Mekki, I. and Vidal, A. (2009). Farmers’ perceptions and engineering approach in the modernization of a community-managed irrigation scheme. A case study from an oasis of the Nefzawa (south of Tunisia). Irrigation and Drainage 58:S285296.CrossRefGoogle Scholar
Hilgeman, R. H. and Reuther, W. (1967). Evergreen tree fruits, Chapter 36. In Irrigation of Agricultural Lands, 704718 (Eds Hagan, R. M., Haise, H. R. and Edminster, T. W.). Madison, WI: American Society of Agronomy.Google Scholar
Hodel, D. R. and Pittenger, D. R. (2003). Studies on the establishment of date palm (Phoenix dactylifera ‘Deglet Noor’) offshoots. Part 1. Observations on root development and leaf growth. Palms 47 (4):191200.Google Scholar
Hussein, F. and Hussein, M. A. (1982). Effect of irrigation on growth, yield and fruit quality of dry dates grown at Asswan. In Proceedings of the 1st Date Palm Conference, Al-Hassa, Saudi Arabia, 168172.Google Scholar
Hussein, F., Mohsen, A. M., Meligi, M. A. and Rizk, S. A. (2007). Studies on stomatal frequency and cuticular depositions in Haiani date pinna. In Proceedings of the Third International Date Palm Conference, Al-Ain, United Arab Emirates, 477483.Google Scholar
Jain, S. M., Al-Khayri, J. M. and Johnson, D. V. (Eds.) (2011). Date Palm Biotechnology. Dordrecht, Netherlands: Springer.Google Scholar
Jaradat, A. A. (2011). Biodiversity of date palm. In Encyclopedia of Life Support Systems: Land Use, Land Cover and Soil Sciences. Oxford, UK: EOLSS, pp. 31.Google Scholar
Kassem, M. A. (2007). Water requirements and crop coefficient of date palm trees ‘Sukriah cv’. . Misr Journal of Agricultural Engineering 24:339359.Google Scholar
Liebenberg, P. J. and Zaid, A. (2002). Date palm irrigation, Chapter 7. In Date Palm Cultivation (Ed Zaid, A.). FAO Plan Production and Protection Paper No. 156, Rome, Italy.Google Scholar
Maas, E. V. (1993). Testing crops for salinity tolerance. In Proceedings of Workshop on Adaptation of Plants to Soil Stresses, 234247 (Eds Baligar, B. V., Duncan, R. R. and Yohe, J. M.). INTSORMIL Publ. No. 94–2. Lincoln, NE: University of Nebraska.Google Scholar
Maas, E. V. and Hoffman, M. (1977). Crop salt tolerance – current assessment. Journal of the Irrigation and Drainage Division (ASCE), 103 (IR2):115134.CrossRefGoogle Scholar
Mazahrih, N. Th., Al-Zu'bi, Y., Ghnaim, H., Lababdeh, L., Ghananeem, M. and Ahmadeh, H. A. (2012). Determination actual evapotranspiration and crop coefficients of date palm trees (Phoenix dactylifera) in the Jordan Valley. American-Eurasian Journal of Agriculture and Environmental Science 12 (4):434443.Google Scholar
Oweis, T. (2004). Agricultural water use in the Arabian Peninsular with extreme scarcity. Paper Presented at ICARDA Regional Meeting on Date Palm Development in the Arabian Peninsular, Abu Dhabi.Google Scholar
Pareek, O. P. (1990). Date palm, Chapter 21. In Fruits: Tropical and Subtropical, 667689 (Eds Bose, T. K. and Mitra, S. K.). Calcutta, India: Naya Prokash.Google Scholar
Perry, C. (2011). Accounting for water use: terminology and implications for saving water and increasing production. Agricultural Water Management 98:18401846.Google Scholar
Purseglove, J. W. (1972). Tropical Crops: Monocotyledons. London: Longman.Google Scholar
Rawlins, S. L. (1977). Uniform irrigation with a low-head bubbler system. Agricultural Water Management 1:167178.Google Scholar
Reuther, W. (1944). Response of Deglet Noor palms to irrigation on a deep sandy soil. In 21st Annual Report Date Growers’ Institute, Coachella Valley, California, 1619.Google Scholar
Reuther, W. and Crawford, C. I. (1945). Irrigation experiments with dates. Date Growers’ Institute Report 22:1114.Google Scholar
Rhoades, J. D. and Loveday, J. (1990). Salinity in irrigated agriculture, Chapter 36. In Irrigation of Agricultural Crops, 10891142 (Eds Stewart, B. A. and Nielsen, D. R.). Madison, WI: American Society of Agronomy.Google Scholar
Ringersma, J., Mechergui, M. and Pijnenburg, S. (1996). Transpiration measurements in date palms using the Granier method. In Evapotranspiration and Irrigation Scheduling, 141146 (Eds Camp, C. R., Sadler, F. J. and Yoder, R. E.). Joseph Charter Township, MI: American Society of Agricultural Engineers.Google Scholar
Saeed, A. B., Etewy, H. A., Duheash, O. A. and Aly-Hassan, O. S. (1986). Assessment of date palm water requirements under Al-Hassa conditions. In Proceedings of the Second Symposium on Date Palm, Al-Hassa, Saudi Arabia, 365374.Google Scholar
Sellami, M. H. and Sifaoui, M. S. (2003). Estimating transpiration in an intercropping system: measuring sap flow inside the oasis. Agricultural Water Management 59:191204.Google Scholar
Tishehzan, P., Naseri, A. A., Hassanoghli, A. R. and Meskarbashi, M. (2011). Effects soil covering and controlled water table on date palm growth and the root zone salt balance in southwest Iran. Paper presented at ICID 21st Congress, Tehran, 539551.Google Scholar
Tomlinson, P. B. (2006). The uniqueness of palms. Botanical Journal of the Linnean Society 151:514.Google Scholar
Tripler, E., Ben-Gal, A. and Shani, U. (2007). Consequence of salinity and excess boron on growth, evapotranspiration and ion uptake in date palm (Phoenix dactylifera, L., cv. Medjool). Plant and Soil 297:147155.Google Scholar
Tripler, E., Shani, U., Ben-Gal, A. and Mualem, Y. (2012). Apparent steady state conditions in high resolution weighing drainage lysimeters containing date palms grown under different salinities. Agricultural Water Management 107:673.Google Scholar
Tripler, E., Shani, U., Mualem, Y. and Ben-Gal, A. (2011). Long-term growth, water consumption and yield of date palm as a function of salinity. Agricultural Water Management 99:128134.Google Scholar
Zaid, A. and de Wet, P. F. (2002a). Botanical and systematic description of the date palm, Chapter 1. In Date Palm Cultivation (Ed Zaid, A.), FAO Plant Production and Protection Paper No. 156, Rome. Rome, Italy: FAO.Google Scholar
Zaid, A. and de Wet, P. F. (2002b). Climatic requirements of date palm, Chapter 4. In Date Palm Cultivation (Ed Zaid, A.), FAO Plant Production and Protection Paper No. 156, Rome. Rome, Italy: FAO.Google Scholar