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The Effect of Different Doses of N Fertilization on the Parameters of Soil Organic Matter and Soil Sorption Complex

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Języki publikacji
EN
Abstrakty
EN
Mineral N fertilizer application may have an effect on soil organic matter and other soil parameters. Therefore, we studied the effects of different doses of N fertilization on soil organic matter and chemical properties of Haplic Luvisol in the locality of Dolná Malanta (Slovakia) during 2014–2016. Soil samples were collected from the plots exposed to the following treatments: 1. N0 – no N fertilization as control during 2014–2016, 2. N40 – N fertilizer at the rate of 40 kg N ha–1 in 2014 and 2016, 3. N80 – N fertilizer at the rate of 80 kg N ha–1 in 2014 and 2016, 4. N160 – N fertilizer at the rate of 160 kg N ha–1 in 2015, and 5. N240 – N fertilizer at the rate of 240 kg N ha–1 in 2015. The results showed that in N80 the soil organic carbon (SOC) content increased by 32% in comparison to N0. The addition of 80 kg ha-1 of N significantly decreased the humic substances (HS) content in the soil by 16% compared to N0. The higher doses of N fertilization 80 rather than 40 kg ha-1 as well as 240 rather than 160 kg ha-1 significantly decreased humus stability. The addition of N fertilization decreased the average values of soil pH. Values of hydrolytic acidity (Ha) increased by 41% and 46% in N40 and N80, respectively than N0, but on the other hand, this one decreased by 36% and 27% in N160 and N240, respectively in comparison to N0. Positive statistically significant correlations were determined between soil pH and SOC in N40 and N80 treatments. The increase of soil pH was connected with higher humus quality in N160 and N240. Negative correlations between humic acids (HA) and sum of basic cations (SBC) and cation exchange capacity (CEC) were observed in N80 < N160 < N240 treatments. Higher values of fulvic acids corresponded with lesser CEC in N80 and N160 treatments. In N160, with increased humus quality, CEC significantly decreased. The same effect was observed in N240. In addition, in N240, we also observed that with increased HA:FA ratio SBC and base saturation significantly decreased.
Rocznik
Strony
104--111
Opis fizyczny
Bibliogr. 32 poz., rys., tab.
Twórcy
  • Department of Soil Science, Faculty of Agrobiology and Food Resources, Slovak University of Agriculture, Tr. A. Hlinku 2, 949 76 Nitra, Slovakia
autor
  • Department of Agrochemistry and Plant Nutrition, Faculty of Agrobiology and Food Resources, Slovak University of Agriculture, Tr. A. Hlinku 2, 949 76 Nitra, Slovakia
autor
  • Department of Soil Environment Sciences, Warsaw University of Life Sciences – SGGW, Poland
Bibliografia
  • 1. Chandel G., Banerjee S., See S., Meena R., Sharma D.J., Verulkar S.B. 2010. Effects of different nitrogen fertilizer levels and native soil properties on rice grain Fe, Zn and protein contents. Rice Science, 17, 213–227.
  • 2. Cheng S., He S., Fang H., Xia J., Tian J., Yu G., Geng J., Yu G. 2017. Contrasting effects of NH4+ and NO3- amendments on amount and chemical characteristics of different density organic matter fractions in a boreal forest soil. Geoderma, 293, 1–9.
  • 3. Chodak M., Pietrzykowski M., Sroka K. Physiological profiles of microbial communities in mine soils afforested with different tree species. Ecolological Enginiering, 81, 462–470.
  • 4. Cusack, D.F., Silver,W.L., Torn, M.S., Burton, S.D., Firestone, M.K. 2011. Changes in microbial community characteristics and soil organicmatter with nitrogen additions in two tropical forests. Ecology, 92, 621–632.
  • 5. Dziadowiec H., Gonet S.S. 1999. Methodical guide-book for soil organic matter studies. Polish Society of Soil Science, Warszawa (in Polish).
  • 6. Fecenko J., Ložek O. 2000. Nutrition and fertilization of field crops. Slovak University of Agriculture, Nitra (in Slovak).
  • 7. Halvorson, A.D., Wienhold, B.J., Black, A.L. 2002. Tillage, nitrogen, and cropping system effects on soil carbon sequestration. Soil Science Society of American Journal, 66, 906–912.
  • 8. Hanes J. 1999. Analyzes of sorptive characteristics. SSCRI, Bratislava (in Slovak).
  • 9. Hati, K.M., Swarup, A., Singh, D., Misra, A.K., Ghosh, P.K. 2006. Long term continuous cropping, fertilisation, and manuring effects on physical properties and organic carbon content of a sandy loam soil. Aust. J. Soil Res., 44(5), 487–495.
  • 10. Jagadamma S., Lal R., Hoeft R.G., Nafziger, E.D., Adee, E.A. 2007. Nitrogen fertilization and cropping systems effects on soil organic carbon and total nitrogen pools under chisel-plow tillage in Illinois. Soil and Tillage Research, 95, 348–356.
  • 11. Kaur T., Brar B.S., Dhillon N.S. 2008. Soil organic matter dynamics as affected by long-term use of organic and inorganic fertilizers under maize-wheat cropping system. Nutrients Cycling of Agroecosystem, 81, 59–69.
  • 12. Li Z.Q., Zhao B.Z., Wang Q.Y., Cao X.Y., Zhang J.B. 2015. Differences in chemical composition of soil organic carbon resulting from long-term fertilization strategies. PLoS One, 10(4), 1–14.
  • 13. Li, Y., Zhang, J., Chang, S.X., Jiang, P., Zhou, G., Fu, S., Yan, E.,Wu, J., Lin, L. 2013. Long-term intensivemanagement effects on soil organic carbon pools and chemical composition in Moso bamboo (Phyllostachys pubescens) forests in subtropical China. Forest Ecology and Management, 303, 121–130.
  • 14. Luo, Z.,Wang, E., Smith, C. 2015. Fresh carbon input differentially impacts soil carbon decomposition across natural and managed systems. Ecology, 96, 2806–2813.
  • 15. Munkholm L.J., Schjonning P., Debosz K., Jensen H.E., Christensen B.T. 2002. Aggregate strength and mechanical behaviour of a sandy loam soil under long-term fertilization treatments. European Journal of Soil Science, 53, 129–137.
  • 16. Neff J.C., Townsend A.R., Gleixner G., Lehman S.J., Turnbull J., Bowman W.D. 2002. Variable effects of nitrogen additions on the stability and turnover of soil carbon. Nature, 419, 915–917.
  • 17. Pelster D.E., Larouche F., Rochette P., Chantigny M.H., Allaire S., Angers D.A. 2011. Nitrogen fertilization but not soil tillage affects nitrous oxide emissions from a clay loam soil under a maize–soybean rotation. Soil and Tillage Research, 115–116, 16–26.
  • 18. Purakayastha T.J., Kumari S., Pathak H. 2015. Characterisation, stability, and microbial effects of four biochars produced from crop residues. Geoderma, 239–240, 293–303.
  • 19. Sainju, U.M., Jabro, J.D., Stevens,W.B. 2008. Soil carbon dioxide emission and carbon content as affected by irrigation, tillage, cropping system, and nitrogen fertilization. Journal of Environmental Quality, 37, 98–106.
  • 20. Schmidt, M.W., Torn, M.S., Abiven, S., Dittmar, T., Guggenberger, G., Janssens, I.A., Kleber, M., Kögel-Knabner, I., Lehmann, J., Manning, D.A. 2011. Persistence of soil organic matter as an ecosystem property. Nature, 478, 49–56.
  • 21. Shisanya C.A., Mucheru M.W., Mugendi D.N., Kungu J.B. 2009. Effect of organic and inorganic nutrient sources on soil mineral nitrogen and maize yields in central highlands of Kenya. Soil and Tillage Research, 103, 239–246.
  • 22. Šimanský V. 2015. Fertilization and carbon sequestration. Acta fytotechnica et zootechnica, 18(3), 56–62.
  • 23. Šimanský V., Polláková N. 2014. Soil organic matter and sorption capacity under different soil management practices in a productive vineyard. Archives of Agronomy and Soil Science, 60(8), 1145–1154.
  • 24. Šimanský V., Tobiašová E. 2010. Impact of tillage, fertilization and previous crop on chemical properties of Luvisol under barley farming system. Journal of Central Eurepean Agriculture, 11(3),245–254.
  • 25. Šimanský V., Tobiašová E. 2012. Organic matter and chemical properties in Haplic Luvisol as affected by tillage and fertilizers intensity. Acta fytotechnica et zootechnica, 15(2), 52–56.
  • 26. Stevenson J.F. 1994. Humus chemistry. John Wiley & Sons, New York.
  • 27. Subbian P., Lal R., Akala V. 2000. Long-term effects of cropping systems and fertilizers on soil physical properties. Journal of Sustainable Agriculture, 16, 89–100.
  • 28. Szombathová N. 2010. Chemical and physicochemical properties of soil humus substances as an indicator of anthropogenic changes in ecosystems (Báb a Dolná Malanta localities). Slovak University of Agriculture, Nitra (in Slovak).
  • 29. Triberti L., Nastri A., Giordani G., Comellini F., Baldoni G., Toderi, G. 2008. Can mineral and organic fertilization help sequestrate carbon dioxide in cropland? European Journal of Agronomy, 29, 13–20.
  • 30. World Reference Base for Soil Resources. 2006. World Soil Resource Report No. 84. Food and Agriculture Organisation of the United Nations, Rome.
  • 31. Zalba P., Quiroga A.R. 1999. Fulvic acid carbon as a diagnostic feature for agricultural soil evaluation. Soil Science, 164, 57–61.
  • 32. Zornoza R., Acosta J.A., Faz A., Bååth E. 2016. Microbial growth and community structure in acid mine soils after addition of different amendments for soil reclamation. Geoderma, 272, 64–72.
Uwagi
Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę (zadania 2017).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-956a7094-6393-4440-8d2f-9b14647be90b
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