WATER ABSORBING GEOCOMPOSITE: A NOVEL METHOD IMPROVING WATER AND FERTILIZER EFFICIENCY IN Brunnera macrophylla CULTIVATION. PART II. PROPERTIES OF THE MEDIUM AND MACROELEMENT UPTAKE EFFICIENCY
Katarzyna Wróblewska
Department of Horticulture, Wrocław University of Environmental and Life Sciences, Grunwaldzki Sq. 24 a, 50-363 WrocławPiotr Chohura
Department of Horticulture, Wrocław University of Environmental and Life Sciences, Grunwaldzki Sq. 24 a, 50-363 WrocławKrzysztof Lejcuś
Institute of Environmental Engineering, Wrocław University of Environmental and Life Sciences, Grunwaldzki Sq. 24, 50-363 WrocławJolanta Dąbrowska
Institute of Environmental Engineering, Wrocław University of Environmental and Life Sciences, Grunwaldzki Sq. 24, 50-363 WrocławPrzemysław Bąbelewski
Institute of Environmental Engineering, Wrocław University of Environmental and Life Sciences, Grunwaldzki Sq. 24, 50-363 WrocławAbstract
The aim of the study was to determine the effect of the geocomposite (GC) on macronutrient uptake of container-grown Brunnera macrophylla and substrate properties. The GC consists of super-absorbent polymer (SAP), internal skeleton and non-woven geotextile. It was designed to retain water in the soil in a form available for plants, by roots overgrowing the geotextile to access water. The GC was soaked in a multi-compound fertilizer (Insol® U) and compared with soluble fertilizer (SF) and controlled-release fertilizer (CRF). The fertilizer rates were calculated to cover the equal N supply: 0.36 and 0.72 g N plant−1. Nitrogen uptake of Brunnera cultivated with the geocomposite was approximately twice and three times as high as that of plants fertilized with SF and CRF, respectively. Exceptionally high N content was observed in plants cultivated with the GC-0.72 g N plant−1. The use of the GC also enhanced the accumulation of K and P, while CRF strongly reduced their content in plants. Distinct relations could be observed in the case of Ca accumulation. GC-0.72 g N plant−1 increased EC and water content in the medium without direct contact between SAP and substrate.
Keywords:
container nursery, microelements content, nutrient use efficiency, superabsorbent polymersReferences
Abd El-Rehim, H.A. (2006). Characterization and possible agricultural application of polyacrylamide/sodium alginate crosslinked hydrogels prepared by ionizing radiation. J. Appl. Polym. Sci., 101(6), 3572–3580.
Andiru, G., Pasian, C.C., Frantz, J.M., Jones, M.L. (2013). Greenhouse production of Impatiens wallerana using a controlled-release fertilizer produces quality finished plants with enhanced garden performance. J. Hortic. Sci. Biotechnol., 88(2), 216–222.
Bowman, D.C., Evans, R.Y. (1991). Calcium inhibition of polyacrylamide gel hydration is partially reversible by potassium. HortScience, 26(8), 1063–1065.
Bres, W., Weston, L.A. (1993). Influence of gel additives on nitrate, ammonium, and water-retention and tomato growth in a soilless medium. HortScience, 28(10), 1005–1007.
Buchholz, F.L., Graham, A.T. (1997). Modern superabsorbent polymer technology. Wiley-VCH, New York.
Cabala, A., Wroblewska, K., Chohura, P., Debicz, R. (2016). Effect of fertilization through geocomposite on nutritional status of Hosta 'halcyon' plants grown in containers. Acta Sci. Pol. Hortorum Cultus, 15(3), 83–93.
Faithfull N.T., (2002). Methods in agricultural chemical analysis: a practical handbook. CAB Publishing, New York.
Foster, W.J., Keever, G.J. (1990). Water absorption of hydrophilic polymers (hydrogels) reduced by media amendments. J. Environ. Hortic., 8(3), 113–114.
Gao, H.F., Bai, J.H., He, X.H., Zhao, Q.Q., Lu, Q.Q., Wang, J.J. (2014). High temperature and salinity enhance soil nitrogen mineralization in a tidal freshwater marsh. Plos One, 9(4), 9.
Huttermann, A., Orikiriza, L.J.B., Agaba, H. (2009). Application of superabsorbent polymers for improving the ecological chemistry of degraded or polluted lands. Clean-Soil Air Water, 37(7), 517–526.
Kazanskii, K.S., Dubrovskii, S.A. (1992). Chemistry and physics of agricultural hydrogels. Adv. Polym. Sci., 104, 97–133.
Kocarek, M., Kodesova, R. (2012). Influence of temperature on soil water content measured by ECH2O-TE sensors. Int. Agrophys., 26(3), 259–269.
Korkalainen, T., Pietilainen, P., Colpaert, A. (2007). The effect of total peat nitrogen on the height and volume of Scots pine (Pinus sylvestris L.) stands in three fertilized and drained peatlands in northern Finland. Suo 58(3–4), 75–85.
Laftah, W.A., Hashim, S., Ibrahim, A.N. (2011). Polymer Hydrogels: A Review. Polym.-Plast. Technol. Eng., 50(14), 1475–1486.
Lejcus, K., Dabrowska, J., Garlikowski, D., Kordas, L. (2015a). Water loss from soil and water absorbing geocomposite. Int. Proc. Chem. Biol. Environ. Eng., 84(21), 123–127.
Lejcus, K., Dabrowska, J., Garlikowski, D., Spitalniak, M. (2015b). The application of water-absorbing geocomposites to support plant growth on slopes. Geosynth. Int., 22(6), 452–456.
Lejcus, K., Dabrowska, J., Grzybowska-Pietras, J., Garlikowski, D., Lejcus, I., Pawlowski, A., Spitalniak, M. (2016). Optimisation of operational parameters for nonwoven sheaths of water absorbing geocomposites in unsaturated soil conditions. Fibres Text. East. Eur., 24(3), 110–116.
Mettrop, I.S., Cusell, C., Kooijman, A.M., Lamers, L.P.M. (2014). Nutrient and carbon dynamics in peat from rich fens and Sphagnumfens during different gradations of drought. Soil Biol. Biochem., 68, 317–328.
Mikkelsen, R.L. (1994). Using hydrophilic polymers to control nutrient release. Fertil. Res., 38(1), 53–59.
Mikkelsen, R.L., Behel, A.D., Williams, H.M. (1993). Addition of gelforming hydrophilic polymers to nitrogen-fertilizer solutions. Fertil. Res., 36(1), 55–61.
Nowosielski O., (1974). Methods of determination of nutritional requirements, 2nd ed. PWRiL, Warsaw.
Oksinska, M.P., Magnucka, E.G., Lejcus, K., Pietr, S.J. (2016). Biodegradation of the cross-linked copolymer of acrylamide and potassium acrylate by soil bacteria. Environ. Sci. Pollut. Res., 23(6), 5969–5977.
Sita, R.C.M., Reissmann, C.B., Marques, R., de Oliveira, E., Taffarel, A.D. (2005). Effect of polymers associated with N and K fertilizer sources on Dendrathema grandiflorum growth and K, Ca and Mg relations. Braz. Arch. Biol. Technol., 48(3), 335–342.
Syvertsen, J.P., Dunlop, J.M. (2004). Hydrophilic gel amendments to sand soil can increase growth and nitrogen uptake efficiency of citrus seedlings. HortScience, 39(2), 267–271.
Wang, Y.T., Gregg, L.L. (1990). Hydrophilic polymers – their response to soil amendments and effect on properties of a soilless potting mix. J. Am. Soc. Hortic. Sci., 115(6), 943–948.
Wroblewska, K., Chohura, P., Debicz, R., Lejcus, K., Dabrowska, J. (2018). Water absorbing geocomposite: a novel method improving water and fertilizer efficiency in Brunnera macrophylla cultivation. Part I. Plant growth. Acta Sci. Pol. Hortorum Cultus, 17(6), 49–56.
Wroblewska, K., Debicz, R., Babelewski, P. (2012). The influence of water sorbing geocomposite and pine bark mulching on growth and flowering of some perennial species. Acta Sci. Pol. Hortorum Cultus, 11(2), 203–216.
Yang, L.X., Yang, Y., Chen, Z., Guo, C.X., Li, S.C. (2014). Influence of super absorbent polymer on soil water retention, seed germination and plant survivals for rocky slopes eco-engineering. Ecol. Eng., 62, 27–32.
Zaman, M., Chang, S.X. (2004). Substrate type, temperature, and moisture content affect gross and net N mineralization and nitrification rates in agroforestry systems. Biol. Fertil. Soils, 39(4), 269–279.
Zheng, T., Liang, Y., Ye, S., He, Z. (2009). Superabsorbent hydrogels as carriers for the controlled-release of urea: Experiments and a mathematical model describing the release rate. Biosyst. Eng., 102(1), 44–50.
Zohuriaan-Mehr, M.J., Omidian, H., Doroudiani, S., Kabiri, K. (2010). Advances in non-hygienic applications of superabsorbent hydrogel materials. J. Mater. Sci., 45(21), 5711–5735.
Department of Horticulture, Wrocław University of Environmental and Life Sciences, Grunwaldzki Sq. 24 a, 50-363 Wrocław
Department of Horticulture, Wrocław University of Environmental and Life Sciences, Grunwaldzki Sq. 24 a, 50-363 Wrocław
Institute of Environmental Engineering, Wrocław University of Environmental and Life Sciences, Grunwaldzki Sq. 24, 50-363 Wrocław
Institute of Environmental Engineering, Wrocław University of Environmental and Life Sciences, Grunwaldzki Sq. 24, 50-363 Wrocław
Institute of Environmental Engineering, Wrocław University of Environmental and Life Sciences, Grunwaldzki Sq. 24, 50-363 Wrocław
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