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Vol. 2 No. 2 (2003)

Articles

Nutrient and water uptake in different stages of maturity of greenhouse tomato grown on NFT at different sulphate levels in nutrient solution

DOI: https://doi.org/10.24326/asphc.2003.2.5
Submitted: July 21, 2022
Published: 2003-12-31

Abstract

The aim of a study was to determine the nutrient and water uptake by tomato plant grown in three independent systems of the nutrient film technique (NFT), provided with the nutrient solutions containing different levels of sulphates: I – 200, II – 400, i III –600 mg dm-3. Nutrient and water uptake depended mainly on stages of plant maturity, and in a less degree on the concentration of sulphates in the solution. Average daily uptake by single plant was (mg): nitrogen – 131.4; phosphorus – 31.6; potassium – 229.6; calcium – 100.7; magnesium –23.2. Average daily uptake of water was 1084 cm3.

References

Adams P., 1994. Nutrition of greenhouse vegetables in NFT and hydroponic system. Acta Hort. 361, 245–257.
Adams P., Ho L.C., 1995. Uptake and distribution of nutrients in relation to tomato fruit uality. Acta Hort. 412, 374–385.
Adams P., 1999. Plant nutrition demystified. Acta Hort. 481, 341–344.
Cerda A., Martinez V., Caro M., Fernandez F. G., 1984. Effect of sulfur deficiency and excess on yield and sulfur accumulation in tomato plants. J. Plant Nutr. 7, 1529–1543.
Gertsson U. E., 1995. Nutrient uptake by tomatoes grownin hydroponics. Acta Hort. 401, 351–356.
He Y., Terabayashi S., Asaka T, Namiki T., 1999. Effect of restricted supply of nitrate on fruit growth and nutrient concentrations in the petiole sap of tomato cultured hydroponically. J. Plant Nutr. 22(4–5), 799–811.
Heinen M., Marcelis L. F. M., Elings A., Figueroa R., 2002. Effects of EC and fertigation strategy on water and nutrient uptake of tomato plants. Acta Hort. 593, 101–107.
Kowalska I., Sady W., 2003. Effects of different sulphate levels at the root zone on the concentration of mineral compounds in the leaves of greenhouse tomato grown on NFT. Acta Hort. 604 (2), 499–504.
Lopez J., Tremblay N., Voogot W., Dube S., Gosselin A., 1996. Effects of varying sulphate concentrations on growth, physiology and yield of the greenhouse tomato. Sci. Hort. 67, 207–217.
Lopez J., Christopher I. B., Tremblay N., Dorais M., Gosselin A., 2002. Uptake and translocation of sulphate in tomato seedlings in relation to sulphate supply. J. Plant Nutr. 25(7), 1471–1485.
Marschner H., 1995. Mineral nutrition of higher plants. 2nd edition, Academic Press, London.
Nowosielski O., 1988. Zasady opracowywania zalece nawozowych w ogrodnictwie. PWRiL Warszawa.
Nukaya A., Hashimoto H., 2000. Effects of nitrite, chloride and sulfate ratios and concentration in the nutrient solution on yield growth and mineral uptake characteristics of tomato plants grown in closed rockwool system. Acta Hort. 511, 165–171.
Papadopoulos A. P., Hao X. Tu J. C., Zheng J., 1999. Tomato production in open or closed rockwool culture systems with NFT or rockwool nutrient feedings. Acta Hort. 481, 89–96.
Schwarz D., Kuchenbuch R., 1998. Water uptake by tomato plants grown in closed hydroponic systems dependent on the EC-level. Acta Hort. 458, 323–328.
Wysocka-Owczarek M., 2001, Pomidory pod osłonami. Uprawa tradycyjna i nowoczesna. Hortpress, Warszawa.

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