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Effects of salinity on fruit yield and quality of tomato grown in soil-less culture in greenhouses in Mediterranean climatic conditions

Author

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  • Magán, J.J.
  • Gallardo, M.
  • Thompson, R.B.
  • Lorenzo, P.

Abstract

There is increasing pressure to reduce water use and environmental impact associated with open system, soil-less production in simple, plastic greenhouses on the Mediterranean coast. This may force the adoption of re-circulation of nutrient solutions. In south-eastern Spain, irrigation water is mostly from aquifers and has moderate levels of salinity. The adoption of re-circulation using moderately saline water requires detailed information of crop response to salinity, in order to optimise management. The effect of salinity on fruit yield, yield components and fruit quality of tomato grown in soil-less culture in plastic greenhouses in Mediterranean climate conditions was evaluated. Two spring growing periods (experiments 1 and 2) and one long season, autumn to spring growing period (experiment 3) studies were conducted. Two cultivars, 'Daniela' (experiment 1) and 'Boludo' (experiments 2 and 3), were used. Seven levels of electrical conductivity (EC) in the nutrient solution were compared in experiment 1 (2.5-8.0 dS m-1) and five levels in experiments 2 and 3 (2.5-8.5 dS m-1). Total and marketable yield decreased linearly with increasing salinity above a threshold EC value (ECt). There were only small effects of climate and cultivar on the ECt value for yield. Average threshold EC values for total and marketable fruit yield were, respectively, 3.2 and 3.3 dS m-1. The linear reductions of total and marketable yield with EC above ECt showed significant differences between experiments, the slope varying from 7.2% (autumn to spring period, 'Boludo') to 9.9% (spring period, 'Boludo') decreases per dS m-1 increase in EC for total yield, and from 8.1% (spring period, 'Daniela') to 11.8% (spring period, 'Boludo') for marketable yield. The decrease of fresh fruit yield with salinity was mostly due to a linear decrease of the fruit weight of 6.1% per dS m-1 from an ECt of 3.0 dS m-1 for marketable fruits. Reduction in fruit number with salinity made a smaller relative contribution to reduced yield. Blossom-end rot (BER) increased with increasing salinity. There was a higher incidence of BER with spring grown crops, and 'Boludo' was more sensitive than 'Daniela'. Increasing salinity improved various aspects of fruit quality, such as: (i) proportion of 'Extra' fruits (high visual quality), (ii) soluble solids content, and (iii) titratable acidity content. However, salinity decreased fruit size, which is a major determinant of price. An economic analysis indicated that the EC threshold value above which the value of fruit production decreased linearly with increasing salinity was 3.3 dS m-1, which was the same as that for marketable yield. In the economic analysis, the value of increased visual fruit quality was offset by reduced yield and smaller fruit size.

Suggested Citation

  • Magán, J.J. & Gallardo, M. & Thompson, R.B. & Lorenzo, P., 2008. "Effects of salinity on fruit yield and quality of tomato grown in soil-less culture in greenhouses in Mediterranean climatic conditions," Agricultural Water Management, Elsevier, vol. 95(9), pages 1041-1055, September.
    • Handle: RePEc:eee:agiwat:v:95:y:2008:i:9:p:1041-1055
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    Cited by:

    1. Rigane, Manel Kammoun & Medhioub, Khaled, 2011. "Assessment of properties of Tunisian agricultural waste composts: Application as components in reconstituted anthropic soils and their effects on tomato yield and quality," Resources, Conservation & Recycling, Elsevier, vol. 55(8), pages 785-792.
    2. Zheng, W.W. & Chun, I.J. & Hong, S.B. & Zang, Y.X., 2013. "Vegetative growth, mineral change, and fruit quality of ‘Fuji’ tree as affected by foliar seawater application," Agricultural Water Management, Elsevier, vol. 126(C), pages 97-103.
    3. Gallardo, M. & Thompson, R.B. & Rodríguez, J.S. & Rodríguez, F. & Fernández, M.D. & Sánchez, J.A. & Magán, J.J., 2009. "Simulation of transpiration, drainage, N uptake, nitrate leaching, and N uptake concentration in tomato grown in open substrate," Agricultural Water Management, Elsevier, vol. 96(12), pages 1773-1784, December.
    4. Incrocci, Luca & Thompson, Rodney B. & Fernandez-Fernandez, María Dolores & De Pascale, Stefania & Pardossi, Alberto & Stanghellini, Cecilia & Rouphael, Youssef & Gallardo, Marisa, 2020. "Irrigation management of European greenhouse vegetable crops," Agricultural Water Management, Elsevier, vol. 242(C).
    5. Cabrera Corral, Francisco Javier & Bonachela Castaño, Santiago & Fernández Fernández, María Dolores & Granados García, María Rosa & López Hernández, Juan Carlos, 2016. "Lysimetry methods for monitoring soil solution electrical conductivity and nutrient concentration in greenhouse tomato crops," Agricultural Water Management, Elsevier, vol. 178(C), pages 171-179.
    6. María Ángeles Botella & Virginia Hernández & Teresa Mestre & Pilar Hellín & Manuel Francisco García-Legaz & Rosa María Rivero & Vicente Martínez & José Fenoll & Pilar Flores, 2021. "Bioactive Compounds of Tomato Fruit in Response to Salinity, Heat and Their Combination," Agriculture, MDPI, vol. 11(6), pages 1-12, June.
    7. Daniele Massa & Domenico Prisa & Sara Lazzereschi & Sonia Cacini & Gianluca Burchi, 2018. "Heterogeneous response of two bedding plants to peat substitution by two green composts," Horticultural Science, Czech Academy of Agricultural Sciences, vol. 45(3), pages 164-172.
    8. Bonachela, Santiago & Fernández, María Dolores & Cabrera-Corral, Francisco Javier & Granados, María Rosa, 2022. "Salt and irrigation management of soil-grown Mediterranean greenhouse tomato crops drip-irrigated with moderately saline water," Agricultural Water Management, Elsevier, vol. 262(C).
    9. Cedeño, J. & Magán, J.J. & Thompson, R.B. & Fernández, M.D. & Gallardo, M., 2023. "Reducing nutrient loss in drainage from tomato grown in free-draining substrate in greenhouses using dynamic nutrient management," Agricultural Water Management, Elsevier, vol. 287(C).
    10. Pedro Garcia-Caparros & Juana Isabel Contreras & Rafael Baeza & Maria Luz Segura & Maria Teresa Lao, 2017. "Integral Management of Irrigation Water in Intensive Horticultural Systems of Almería," Sustainability, MDPI, vol. 9(12), pages 1-21, December.
    11. Han, Xiaoyu & Kang, Yaohu & Wan, Shuqin & Li, Xiaobin, 2022. "Effect of salinity on oleic sunflower (Helianthus annuus Linn.) under drip irrigation in arid area of Northwest China," Agricultural Water Management, Elsevier, vol. 259(C).
    12. Gallego-Elvira, B. & Reca, J. & Martin-Gorriz, B. & Maestre-Valero, J.F. & Martínez-Alvarez, V., 2021. "Irriblend-DSW: A decision support tool for the optimal blending of desalinated and conventional irrigation waters in dry regions," Agricultural Water Management, Elsevier, vol. 255(C).
    13. Neocleous, Damianos & Nikolaou, Georgios & Ntatsi, Georgia & Savvas, Dimitrios, 2021. "Nitrate supply limitations in tomato crops grown in a chloride-amended recirculating nutrient solution," Agricultural Water Management, Elsevier, vol. 258(C).
    14. Reca, J. & Trillo, C. & Sánchez, J.A. & Martínez, J. & Valera, D., 2018. "Optimization model for on-farm irrigation management of Mediterranean greenhouse crops using desalinated and saline water from different sources," Agricultural Systems, Elsevier, vol. 166(C), pages 173-183.
    15. Fernando Paniagua & Blanca María Plaza & Alfonso Llanderal & Pedro García-Caparrós & María Teresa Lao, 2023. "Sustainable Strategies Based on Reused Leachates and Hydrogen Peroxide Supply to Fertigate Cordyline fruticosa var. ‘Red Edge’ Plants," Agriculture, MDPI, vol. 13(7), pages 1-19, June.
    16. Li, Jingang & He, Pingru & Chen, Jing & Hamad, Amar Ali Adam & Dai, Xiaoping & Jin, Qiu & Ding, Siyu, 2023. "Tomato performance and changes in soil chemistry in response to salinity and Na/Ca ratio of irrigation water," Agricultural Water Management, Elsevier, vol. 285(C).

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