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Vol. 20 No. 5 (2021)

Articles

Effects of dose of pyrophyllite on yield and quality of the cabbage

DOI: https://doi.org/10.24326/asphc.2021.5.3
Submitted: July 14, 2020
Published: 2021-10-29

Abstract

In this study was researched the influence of the pyrophyllite as a nutrient, bio-stabilizer, soil conditioner, as the adsorbent in different combinations and correlated standard quantitative relations with mineral fertilizers (NPK 15 : 15 : 15), on the yield and nutritional value of Bravo cabbage (Brassica oleraceae var. capitata). Within the examined factor of fertilization treatment, the following variances were represented: a1 – 800 kg ha–1 NPK 15 : 15 : 15 (control plot), a2 – 800 kg ha–1 NPK 15 : 15 : 15 + 2200 kg ha–1 pyrophyllite, a3 – 800 kg ha–1 NPK 15 : 15 : 15 + 1700 kg ha–1 of pyrophyllite, a4 – 800 kg ha–1 NPK 15 : 15 : 15 + 1200 kg ha–1 of pyrophyllite, a5 – 800 kg ha–1 NPK 15 : 15 : 15 + 700 kg ha–1 of pyrophyllite. The purpose of this research was to determine the extent to which the components of the yield and nutritional quality of cabbage depend on the different applied doses of pyrophyllite. The results indicate the fact that the treatments with the application of higher participation of pyrophyllite had a positive effect on the weight and quality of the cabbage head in relation to the control variance.

References

  1. Andrić, Lj. (2010). Modern refractory materials based on pyrophyllite intended for power plants. Institute for Technology of Nuclear and Other Mineral Raw Materials (ITNMS), Belgrade.
  2. Ćirić, M. (1984). Pedology. Institute for Textbooks and Teaching Aids, Sarajevo.
  3. Cvetković, B. (2014). Application of technological procedures of spontaneous fermentation and osmotic dehydration for improving the nutritional profile, sensory properties, and sustainability of cabbage. University of Novi Sad – Faculty of Technology – Department Food Biotechnology [trans. from Serbian].
  4. Drits, V.A., Guggenheim, S., Zviagina, B.B., Kogure, T. (2012). Structures of the 2 : 1 layers of pyrophyllite and talc. ClaysClayMiner., 60(6), 574–587.
  5. Harbi Lab Ltd. Sarajevo (2016). Geological study of reserves and quality of pyrophyllite of “Parsovići – Konjic”. Mining and Geology Institute and Faculty of Mining and Geology in Tuzla.
  6. Holzapfel W., Schillinger U., Buckenhüskes H., Farnworth E. (2003). Sauerkraut. In: Handbook of fermented functional foods. CRC Press, 343–360.
  7. Hodžić, A. (2016). Pyrophyllite is the Future of Ecology – International Fair of Energy, Mining, Environmental Protection and Related Industries – Sarajevo, 19th – 21st June 2018.
  8. Kantoci, D. (2006). Growing of Brassica. Glas. Zašt. Bilja, 29(4), 35–40.
  9. Malinowska-Pańczyk E. (2012). Fermented vegetables products. In: Fermentation. Effects on food properties, Mehta, B.M., Kamal-Eldin, A., Iwanski, R.Z. (eds.). Boca Raton.
  10. Martínez, S., Olmos, I., Carballo, J., Franco, I. (2010). Quality parameters of Brassica spp. grown in northwest Spain. Int. J. Food Sci. Technol., 45, 776–783.
  11. Matotan, Z. (2004). Modern Vegetable Production. Institute for Editions, Zagreb.
  12. Murtić, S., Zahirović, Ć., Karić, L., Jurković, J., Čivić, H., Sijahović, E. (2020a). Use of pyrophyllite as soil conditioner in lettuce production. Nat. Envir. Poll. Technol., 19(1), 355–359.
  13. Murtić, S. Čivić, H., Sijahović, E., Koleška, I., Jurković, J, Tvica, M. (2020b). Use of pyrophyllite to reduce heavy metals mobility in a soil environment. Agron. Res., 18(1), 194–205.
  14. Niketić A.G. (1988). Technology of fruits and vegetables. Sci. J. Fac. Agric. Belgrade, 139–158.
  15. Lazić, B. (1998). Window to Bio Garden, Institute of Field and Vegetable Crops. Novi Sad, 321
  16. Stoiljković, S. (2002). Application of some mineral raw materials in modern agriculture. J. Sci. Papers, 1, 86–92.

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