Hostname: page-component-76fb5796d-9pm4c Total loading time: 0 Render date: 2024-04-25T11:22:15.724Z Has data issue: false hasContentIssue false
  • English
  • Français

Impact of sustained-deficit irrigation on tree growth, mineral nutrition, fruit yield and quality of mango in Spain

Published online by Cambridge University Press:  29 July 2011

Víctor Hugo Durán Zuazo ,
Carmen Rocío Rodríguez Pleguezuelo  and
Dionisio Franco Tarifa
Víctor Hugo Durán Zuazo*
Affiliation:
IFAPA Cent. Torres-Tomejil, Carret. Sevilla-Cazalla km 12,2, 41200, Alcalá del Río, Sevilla, Spain
Carmen Rocío Rodríguez Pleguezuelo
Affiliation:
IFAPA Centro Camino de Purchil, Apdo. 2027, 18080 Granada, Spain
Dionisio Franco Tarifa
Affiliation:
Finca “El Zahorí”, Patron. Cultiv. Subtrop., Plaza de la Constitución 1, Almuñécar (Granada), Spain
*
Correspondence and reprints
Get access

Abstract

Introduction Mango (Mangifera indica L.) is a crop of major economic importance in the provinces of Malaga and Granada (SE Spain). A field experiment on mango trees was designed to determine the optimum irrigation scheduling over three seasons. The aim was to evaluate the impact of sustained-deficit irrigation (SDI) strategies on fruit yield and quality, tree growth, and mineral status under a Mediterranean subtropical climate. Materials and methods. Three sustained-deficit irrigation treatments were applied to mango trees: SDI-1 (33% ETc), SDI-2 (50% ETc) and SDI-3 (75% ETc). The stress treatments were compared with a control (C-100) irrigated at 100% ETC. The response of fruit yield, number of fruits, fruit size and quality, and macro- and micronutrients in leaves was determined. Results. The SDI-2 treatment proved to be the most appropriate SDI treatment, since it allowed the trees to reach the highest yield (18.4 t·ha-1) and the best water-use efficiency (7.14 kg·m-3). However, fruit size was higher for trees of the SDI-3 and C-100 treatments, since they reached significantly higher length and width. The total soluble solids were affected by the SDI treatments only for one year, being highest in fruits from trees of the SDI-1 and SDI-2 treatments. Macro- and micronutrients in the leaves were affected by the SDI treatment only for the P, Mg and Mn contents. Conclusion The SDI treatment providing 50% of ETC is recommended for mango orchards in order to attain the highest yields and the best water-use efficiency under a Mediterranean subtropical climate.

Keywords

SpainMangifera indicairrigationwater usesoil water deficitirrigation ratesfruitsgrowthplant nutritionyieldsqualityEspagneMangifera indicairrigationutilisation de l’eaudéficit hydrique du soldose d’irrigationfruitscroissancenutrition des plantesrendementqualitéEspañaMangifera indicariegouso del aguadéficit de humedad en el suelodosis de riegofrutascrecimientonutrición de las plantasrendimientocalidad
Type
Original article
Information
Fruits , Volume 66 , Issue 4 , July 2011 , pp. 257 - 268
Copyright
© 2011 Cirad/EDP Sciences

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

Références

Anon., Statistics, FAOSTAT, Food and Agriculture Organization of the United Nations, Rome, Italy, 2008.
Anon., Mangos, Market Bulletin, Tanzania Agriculture Productivity Program, USAID-TAPP, Tanzania, issue 1, August 2010, 5 p.
Anon., Fresh fruit and vegetables: The EU market for mango, Centre for the Promotion of Imports from Developing Countries, CBI Market Information Database, 2009, 15 p. (www.cbi.eu).
Campbell, R.S., Campbell, C.N., Commercial Florida cultivars, Acta Hortic. 341 (1993) 5559. CrossRefGoogle Scholar
Durán Zuazo V.H., Martínez A., Aguilar J., Tarifa D.F., El cultivo del mango (Mangifera indica L.) en la costa granadina, Durán Z.V.H. (Ed.), Granada, Spain, 2003, 142 p.
Calatrava R.J., González R.M.C., Guirado S.E., Mateo S.J., Descriptores de frutos en cultivares de mangos existentes en España: Caracterización morfológica y comercial, Junta de Andalucía C.A.P., Serie Información Técnica 15/92, Sevilla, Spain, 1993.
English, M., Raja, S.N., Perspectives on deficit irrigation, Agric. Water Manag. 32 (1996) 114. CrossRefGoogle Scholar
Fereres, E., Soriano, M.A., Deficit irrigation for reducing agricultural water use, J. Exp. Bot. 58 (2007) 147159. CrossRefGoogle ScholarPubMed
Lechaudel, M., Joas, J., Caro, Y., Genard, M., Jannoyer, M., Leaf:fruit ratio and irrigation supply affect seasonal changes in minerals, organic acids and sugars of mango fruit, J. Sci. Food Agric. 85 (2005) 251260. CrossRefGoogle Scholar
Anon., Soil survey staff, soil taxonomy. A basic system of soil classification for making and interpreting soil surveys, USDA, Agric. Handbook, No. 436, USA, 1999.
Anon., Métodos Oficiales de Análisis. Tomo III, Secr. Gen. Téc. Minist. Agric. Pesca Aliment. (MAPA), Madrid, Spain, 1994.
Allen R.G., Pereira L.S., Raes D., Smith M., Crop evapotranspiration (guidelines for computing crop water requirements), FAO Irrigation and Drainage, Pap. N56, FAO, Rome, Italy, 1998.
Durán Zuazo V.H., Rodríguez P.C.R., Tarifa D.F., Monitoring the pollution risk and water use in orchard terraces with mango and cherimoya trees by drainage lysimeters, Irrig. Drain. Syst. (2011) (in revision).
Anon., Official methods of analysis of the Association of Official Analytical Chemists, AOAC, 14th ed., Arlington, VA, USA, 1980.
Avilán, R.L., Rodríguez, M., Ruíz, J., Marín, C.R., Selección de patrones de bajo porte en mango, Agron. Trop. 47 (1997) 259270. Google Scholar
Howell T.H., Cuenca R.H., Solomon K.H., Crop yield response, in: Hoffman, G.J., Howell T.A., Solomon K.H. (Eds.), Management of farm irrigations, systems, ASAE, Monogr., USA, 1990, 93–116.
Chapman H.D., Pratt P.F., Method of analysis for soils, plants and waters, Univ. Calif. (Riverside), Berkeley, USA, 1961.
Fiske, S., The colorimetric determination of phosphorus, J. Biol. Chem. 66 (1952) 375400. Google Scholar
Bremner J.M., Total nitrogen, in: Black C.A. (Ed.), Methods of analysis, part. 2, Agronomy 9, Acad. Press, N.Y., USA, 1965, 1149–1178.
Avilán, R.L., Cuatro años de fertilización nitrogenada en mango (Mangifera indica L.) en suelos de la serie Maracay, Agron. Trop. 24 (1974) 97106. Google Scholar
Durán Zuazo, V.H., Rodríguez, P.C.R., Tarifa, D.F., Fruit yield, growth and leaf–nutrient status of mango trees grafted on two rootstocks in a marginal growing area (South-East Spain), Fruits 61 (2006) 18. CrossRefGoogle Scholar
Spreer, W., Ongprasert, S., Hegele, M., Wünsche, J.N., Müller, J., Yield and fruit development in mango (Mangifera indica L. cv. Chok Anan) under different irrigation regimes, Agric. Water Manag. 96 (2009) 574584. CrossRefGoogle Scholar
Pavel, E.W., Villiers, A.J.D., Responses of mango trees to reduced irrigation regimes, Acta Hortic. 646 (2004) 6368. CrossRefGoogle Scholar
Spreer, W., Nagle, M., Neidhart, S., Carle, R., Ongprasert, S., Müller, J., Effect of regulated deficit irrigation and partial rootzone drying on the quality of mango fruits (Mangifera indica L., cv. ’Chok Anan’), Agric. Water Manag. 88 (2007) 173180. CrossRefGoogle Scholar
da Campos, J.H.B., da Silva, V.P.R., de Azevedo, P.V., Borges, C.J.R., Soares, J.M., de Moura, M.S.B., da Silva, B.B., Evapotranspiraςao e produtividade da mangueira sob diferentes tratamentos de irrigaςao, Rev. Bras. Engen. Agríc. Ambient. 12 (2008) 150156. CrossRefGoogle Scholar
Litz R.E., Mango-botany, production and use, CAB Int., Wallingford, U.K., 680 p., 2009.
Sezen, A.M., Yazar, A., Eker, S., Effect of drip irrigation regimes on yield and quality of field grown bell pepper, Agric. Water Manag. 81 (2006) 115131 CrossRefGoogle Scholar
Gattan, S.R., Berenguer, M.J., Connell, J.H., Polito, V.S., Vossen, P.M., Olive oil production as influenced by different quantities of applied water, Agric. Water Manag. 85 (2006) 133140. CrossRefGoogle Scholar
Ponchner, S., Rojas, R., Bornemisza, E., Variación estacional de nutrimentos en árboles de mango (Mangifera indica) en tres suelos del Pacífico Seco de Costa Rica. I. Macronutrimentos, Agron. Costarric. 17 (1993) 2130. Google Scholar
Stassen, P.J.C., Janse van Vuuren B.P.N., Seasonal uptake and utilization of nitrogen by ‘Sensation’ mango trees, Acta Hortic. 455 (1997) 351358. CrossRefGoogle Scholar
Avilán, R.L., Variaciones de los niveles de N, P, K y Ca en las hojas de mango (Mangifera indica L.) a través de un ciclo de producción, Agron. Trop. 21 (1971) 310. Google Scholar
Leopold A.C., Kriedemann P., Plant growth and development, McGraw-Hill, N.Y., USA, 1975.
Young, T.W., Koo, R.C.J., Mineral composition of Florida mango leaves, Proc. Fla. State Hortic. Soc. 82 (1969) 324328. Google Scholar
Durán Zuazo, V.H., Aguilar, J., Martínez, A., Fruit yield, plant growth and nutrient status in mango: effect of rootstocks, Int. J. Fruit Sci. 5 (2005) 321. CrossRefGoogle Scholar
Reuter D.J., Robinson J.B., Plant analysis: an interpretation manual. Fruits, vines and nuts, Inkata Press, Melbourne, Australia, 1986.
Sergent, E., Leal, F., Casanova, E., Niveles foliares de NPK en mango (Mangifera indica L.), Rev. Fac. Agron. 19 (1993) 319328. Google Scholar
Mukherjee, S.K., Current advances on mango research around the world. Tropical and subtropical fruits, Acta Hortic. 57 (1976) 3742. CrossRefGoogle Scholar
Guimarães, P., Nutricao e adubacao da mangueira, Inf. Agropecu. 8 (1982) 2835. Google Scholar
Pathak, R.A., Pandey, R.M., A note on the status of mineral content of inflorescence and fruits at different of their growth in mango (Mangifera indica L. cv. Dashehari), Ind. J. Plant Physiol. 20 (1977) 4143. Google Scholar
Janse van Vuuren, B.P.H., Stassen, P.J.C., Seasonal uptake of macro elements by young bearing ‘Sensation’ mango trees, Acta Hortic. 455 (1977) 167174. Google Scholar
Guzmán, E.C., Mosqueda, V.R., Alcalde, B.S., Martínez, G.A., Macro and micronutrient foliar content variation in mango cv. Manila, Acta Hortic. 455 (1977) 471478. Google Scholar
Jones J.B., Wolf B., Mills H.A., Plant analysis handbook: a practical sampling, preparation, analysis, and interpretation guide, Micro-macro Publ. Inc., Athens, GA, U.S.A., 1991.
Tiffin L.O., Translocation of micronutrients in plants, in: Mortvedt J.J., Giordano P.M., Linsay W.L. (Eds.), Micronutrients in agriculture, Soil Sci. Soc. Am. Inc., Madison, U.S.A., 1972, 199–229.
Roomizadeh, S., Karimian, N., Manganese-iron relationship in soybean grown in calcareous soils, J. Plant Nutr. 19 (1996) 397406. CrossRefGoogle Scholar
Loneragan J.F., The availability and absorption of trace elements in soil-plant system and their relation to movement and concentrations of trace elements in plants, in: Nicholas D.J.D., Egan A.R. (Eds.), Trace elements in soil-plant systems, Acad. Press, Lond., U.K., 1975, 109–134.
Mills H.A., Jones J.B., Plant analysis handbook II, A practical sampling, preparation, analysis and interpretation guide, Micro-Macro Publ. Inc., Athens, GA, U.S.A., 1996.
Mengel K., Kirkby E.A., Principles of plant nutrition, 4th ed., Int. Potash Inst., Berna, Switz., 1987.
Laborem, G., Avilán, R.L., Figueroa, M., Extracción de nutrientes por una cosecha de mango (Mangifera indica L.), Agron. Trop. 29 (1979) 315. Google Scholar
Singh L.B., The mango. Its botany, cultivation and utilization, World Crops Ser. Book, Leonard Hill. Lond., U.K., 1960.
Dick, E., Adopo, N.A., Camara, B., Moudioh, E., Influence of maturity stage of mango at harvest on its ripening quality, Fruits 64 (2009) 1318. CrossRefGoogle Scholar
Guzmán, E.C., Alcalde, B.S., Mosqueda, V.R., Martínez, G.A., Contenido y extracción de algunos nutrimentos por el fruto de mango cv. Manila, Agron. Trop. 46 (1996) 431446. Google Scholar
Avilan R.L., Rodríguez M., Ruiz J., El cultivo del manguero en Venezuela, FONAIAP Ed., Maracay, Venez., 1998.