Managing irrigation of fruit trees using plant water status


Optimum growth and production of fruit crops is strongly linked to managing irrigation water. Various method of estimating tree water requirements have been utilized such as direct and indirect soil, water, and climatic measurements. Due to differences in fruit tree anatomical and morphological structures and their adaptation to excess and deficit soil water content, such estimates of irrigation water requirements may be more suitable for herbaceous plants but not as accurate for trees. Studies on temperate and tropical fruit trees, using apple (Malus domestica) and star-fruit (Averrhoa carambola), respectively, showed that tree water potential is highly correlated to soil water status. Irrigation based on climate data (ET) and monitoring of soil water resulted in no significant differences in soil or tree water status of orchard-grown fruit trees under temperate and subtropical climatic conditions. The results indicated the need for better understanding and utilization of tree physiological parameters for management of irrigation water of fruit crops. This will ultimately lead to achieving optimum yield and fruit quality while conserving water resources.

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Al-Yahyai, R. (2012) Managing irrigation of fruit trees using plant water status. Agricultural Sciences, 3, 35-43. doi: 10.4236/as.2012.31006.

Conflicts of Interest

The authors declare no conflicts of interest.


[1] Fereres, E. (1997) Irrigation scheduling of horticultural crops. Acta Horticulturae, 449, 253-258.
[2] Hillel, D. (1998) Environmental soil physics. Academic Press, New York.
[3] Robinson, T. and Stiles, W. (1995) Maximizing the performance of young apple trees. New York Fruit Quarterly, 3, 10-16.
[4] Hutmacher, R.B., Nightingale, H.I., Rolston, D.E., Biggar, J.W., Dale, F., Vail, S.S. and Peters, D. (1994) Growth and yield responses of almond (Prunus amygdalus) to trickle irrigation. Irrigation Sci-ence, 14, 117-126. doi:10.1007/BF00193133
[5] Ebel, R.C., Proebsting, E.L. and Patterson, M.E. (1993) Regulated deficit irrigation may alter apple maturity, quality, and storage life. HortScience, 28, 141-143.
[6] Ebel, R.C., Proebsting, E.L. and Evans, R.G. (1995) Deficit irrigation to control growth in apple and monitoring fruit growth to schedule irrigation. HortScience, 30, 1229-1232.
[7] Schaffer, B. (1998) Flooding response and water-use efficiency of subtropical and tropical trees in an environmentally-sensitive wetland. Annals of Botany, 81, 475-481. doi:10.1006/anbo.1998.0593
[8] Al-Yahyai, R., Schaffer, B. and Davies, F.S. (2003) Monitoring soil water content for irrigation scheduling in a carambola orchard in a gravelly limestone soil. Proceedings of the Florida State Horticultural Society, 116, 37-41.
[9] Al-Yahyai, R., Davies, F.S., Schaffer, B. and Crane, J.H. (2005) Effect of soil water depletion on growth, yield, and fruit quality of carambola in gravelly loam soil. Proceedings of the Florida State Horticultural Society, 118, 237-241.
[10] Munoz-Carpena, R., Crane, J., Israel, G. and Yurgalevitch, C. (2003) Water conservation survey of Miami-Dade County agricultural and golf course commercial water users. Proceedings of the Florida State Horticultural Society, 116, 15-21.
[11] Li, Y., Crane, J., Boman, B. and Balerdi, C. (2000) Irrigation management survey for tropical fruit crops in South Florida. Proceedings of the Florida State Horticultural Society, 113, 40-42.
[12] Campbell, G.S. and Campbell, M.D. (1982) Irrigation scheduling using soil moisture measurements: Theory and practice. Advances in Irrigation, 1, 25-42.
[13] Jones, H.G. (1990) Physiological aspects of the control of water status in horticultural crops. HortScience, 25, 19-26.
[14] Braun, P., Aspinall, D. and Lenz, F. (1989) The use of physiological indicators of water status in irrigation scheduling in citrus. Acta Horticulturae, 240, 267-270.
[15] Jones, H.G. (2004) Irrigation scheduling: advantages and pitfalls of plant-based methods. Journal of Experimental Botany, 55, 2427-2436. doi:10.1093/jxb/erh213
[16] Hsiao, T. (1990) Measurements of plant water status. p. 243-279. In: Steward, B. and Nielsen, D., Eds., Irrigation of Agricultural Crops, Agronomy Monographs No. 30, ASA, Madison, Wis.
[17] Al-Yahyai, R., Schaffer, B. and Davies, F.S. (2005) Physiological response of carambola to soil water depletion. HortScience, 40, 2145-2150.
[18] Buss, P. (1989) Irrigation scheduling for horticulture: An integrated approach. Acta Horticulturae, 240, 261-270.
[19] Naor, A. and Cohen, S. (2003) Sensitivity and variability of maximum trunk shrinkage, midday stem water potential, and transpiration rate in response to withholding irrigation from field-grown apple trees. HortScience, 38, 547-551.
[20] USDA (United States Department of Agriculture) (1958) Soil Survey. Ontario and Yates Counties, New York, Series 1949, No. 5, 56-57.
[21] Jones, H.G., Luton, M.T., Higgs, K.H. and Hamer, P.J. (1983) Experimental control of water status in an ap-ple orchard. Journal of Horticultural Science, 58, 301-316.
[22] Ley, T.W. (1994). Using PAWS and AgriMet for irrigation scheduling. In: Williams, K.M. and Ley, T.E. Eds., Tree Fruit Irrigation, Good Fruit Grower, Washington DC, 71- 77.
[23] Chanasyk, D.S. and Naeth, M.A. (1996) Field measurement of soil moisture using neutron probes. Canadian Journal of Soil Science, 76, 317-323. doi:10.4141/cjss96-038
[24] Begg, J.E. and Turner, N.C. (1970) Water potential gradients in field tobacco. Plant Physiology, 46, 343-346. doi:10.1104/pp.46.2.343
[25] McCutchan, H. and Shackel, K. (1992) Stem-water potential as a sensitive indicator of water stress in prune trees (Prunus domestica L. cv. French). Journal of the American Society for Horticultural Science, 117, 607- 611.
[26] Shackel, K.A., Ahmadi, H., Biasi, W., Buchner, R., Goldhamer, D., Gurusinghe, S., Hasey, J., Kester, D., Krueger, B., Lampinen, B., McGourty, G., Micke, W., Mitcham, E., Olson, B., Pelletrau, K., Philips, H. Ramos, D., Schwankl, L., Sib-bett, S., Snyder, R., Southwick, S., Stevenson, M., Thorpe, M., Weinbaum, S. and Yeager, J. (1997) Plant water status as an index of irrigation need in deciduous fruit trees. HortTechnology, 7, 23-29.
[27] Noble, C.V., Drew, R.W. and Slabaugh, V. (1996) Soil survey of Dade County area, Florida. U.S. Department of Agriculture, Natural Resources Conservation Service, Washington DC.
[28] Paltineanu, I.C. and Starr, J.L. (1997) Real-time soil water dynamics using multisensor capacitance probes: Laboratory calibration. Soil Science Society of America Journal, 61, 1576-1585. doi:10.2136/sssaj1997.03615995006100060006x
[29] Lord, W.J., Michelson, L.F. and Filed, D.L. (1963) Response of irrigation and moisture use by McIntosh apple tree in Massachusetts. Experiment Station Bulletin, 537, 1-23.
[30] Forshey, G.G. and Dominick, B.A. (1965) Irrigation of apples in the Hudson Valley. New York State Agricultural Experiment Station Bulletin, 809.
[31] Goode, A.J. and Higgs, K.H. (1973) Water, osmotic and pressure potential relationships in apple leaves. Journal of Horticultural Science, 48, 203-215.
[32] Ebel, R.C., Proebsting, E.L. Evans, R.G. and Ley, T.W. (1988) “Delicious” tree and fruit response to duration of drought. HortScience, 23, 723.
[33] Núnez-Elisea, R., Schaffer, B., Zekri, M., O’Hair, S.K. and Crane, J.H. (2001) In situ soil-water characteristic curves for tropical fruit orchards in trenched calcareous soil. HortTechnology, 11, 65-69.
[34] Zekri, M., Núnez-Elisea, R., Schaffer, B., O’Hair, S.K. and Crane, J.H. (1999) Multisensor capacitance probes for monitoring soil water dynamics in the oolitic limestone soil of South Florida. Proceedings of the Florida State Horticultural Society, 112, 178-181.
[35] Al Al-Yahyai, R., Schaffer, B., Davies, F.S. and Crane, J.H. (2005) Four levels of soil water depletion minimally affect carambola phenological cycles. Hort-Technology, 15, 623-630.
[36] Larson, K., Schaffer, B. and Davies, F.S. (1989) Effect of irrigation on leaf water potential growth and yield of mango trees. Proceedings of the Florida State Horticultural Society, 102, 226-228.
[37] Ismail, M.R., Burrage, S.W., Tarmizi, H. and Aziz, M.A. (1994) Growth, plant water relations, photosynthesis rate, and accumulation of proline in young carambola plants in relation to water stress. Scientia Horticulturae, 60, 101-114. doi:10.1016/0304-4238(94)90065-5
[38] Ismail, M.R., Yusaf, M.K. and Masturi. A. (1996) Growth and flowering of water stressed star-fruit plants and response to ameliorated water stress. Proceedings of the International Conference on Tropical Fruits, Kuala Lampur, Malaysia, 2, 97-106.
[39] Razi, M.I., Awang, M. and Razlan, S. (1992) Effect of water stress on growth and physiological processes of Averrhoa carambola. Acta Horticulturae, 321, 505-509.
[40] Naor, A. (2000) Midday stem water potential as a plant water stress indicator for irrigation scheduling in fruit trees. Acta Horticulturae, 537, 447-454.
[41] Stern, R.A., Meron, M., Naor, A. Wallach, R., Bravdo, B. and Gazit, S. (1998) Effect of fall irrigation level in “Mauritius” and “Floridian” lychee on soil and plant water status, flowering maturity, and yield. Journal of the American Society for Horticultural Science, 123, 150-155.
[42] Garnier, E. and Berger, A. (1985) Testing water potential in peach trees as an indicator of water stress. Journal of Horticultural Science, 60, 47-56.

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