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2012 | 21 | 3 |
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Effect of post-harvest residue of maize, rapeseed, and sunflower on humic acids properties in various soils

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The aim of our paper was to determine the properties of humic acids produced as a result of decomposition (under controlled conditions) of post-harvest residue of maize, rapeseed, and sunflower in different soil types (haplic luvisol, chernozems, haplic arenosols, and haplic gleysols). The extraction of humic acids was performed from the samples obtained directly once the post harvest residue was mixed with soil material, and after 360 days of incubation. The properties of humic acids were determined based on elemental analysis HPLC and HPSEC. The qualitative parameters of humic acids demonstrated that introducing sunflower postharvest residue into the soil causes the formation of humic acids typical for soils without any additives. On the other hand, properties of humic acids after introducing maize post-harvest residue into soil are most modified.
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  • Department of Environmental Chemistry, University of Technology and Life Sciences, Bernardynska 6-8, 85-029 Bydgoszcz, Poland
  • 1. STEVENSON F.J. Humus chemistry. Genesis, Composition and Reactions. Wiley-Intersc. Publ. New York, pp. 1-497, 1982.
  • 2. GONET S.S. Habitat and anthropogenic factors determining status of soil organic matter. Humic Subst. Environ. 1, 17, 1997.
  • 3. AOYAMA M„ KUMAKURA N. Quantitative and qualitative changes of organic matter in an Ando soil induced by mineral fertiliser and cattle manure applications for 20 years. Soil Sci. Plant Nutr. 47, (2), 241, 2001.
  • 4. FOLLET R. F. Soil management concepts and carbon sequestration in cropland soil. Soil Till. Res. 61, 77, 2001.
  • 5. DOANE T.A., DEVEVRE O.C., HORWATH W.R. Short-term soil carbon dynamics of humic fractions in low-input and organic cropping systems. Geoderma 114, 319, 2003.
  • 6. EYHERAGUIBEL B., SILVESTRE J., MORARD P. Effects of humic substances derived from organic waste enhancement on the growth and mineral nutrition of maize. Bioresour. Technol. 99, 4206, 2008.
  • 7. ALEKSANDROVA L.N. Soil organic compounds and their transformation processes. Nauka, Leningrad, 1980 [In Russian],
  • 8. GONET S.S., DĘBSKA B. Properties of humic acids developed during humification process of post-harvest plant residues. Environ. Int. 24, (5/6), 603,1998.
  • 9. GONET S.S., DĘBSKA B. Properties of humic acids produced during decomposition of plant residues in soil. Rostlinná Výroba 45, 455,1999.
  • 10. TOBIASOVA E., ZAUJEC A., DĘBSKA B. Nitrogen in crop residue transformation processes. Phytopedon (Bratislava) 4,(1), 50, 2005.
  • 11. ADANI F., RICCA G. The contribution of alkali soluble (humic acid-like) and unhydrolyzed-alkali soluble corehumic acid-like fractions extracted from maize plant to the formation of soil humic acid. Chemosphere 56, 13, 2004.
  • 12. BERG B. Nutrient release from litter and humus in coniferous forest soils - a mini review. Scand. J. For. Res. 1, 359, 1986.
  • 13. MELILLO J.M., ABER J.D., LKINS A.E., RICCA A., FRY B., NADELHOFFER K.J. Carbon and nitrogen dynamics along the decay continuum: plant litter to soil organic matter. Plant and soil 115, 189,1989.
  • 14. TAKEDA H. Decomposition processes of litter along a latitudinal gradient. [In:] Environmental Forest Science, K. Sassa (Ed.), Kluwer Academic Press, Dordrecht, pp. 197- 206,1998.
  • 15. LORENZ K., PRESTON C.M., KRUMREI S., FEGER K.H. Decomposition of needle/leaf litter from Scots pine, black cherry, common oak and European beech at a conurbation forest site. Eur. J. Forest Res. 123, 177, 2004.
  • 16. OSANO T., TAKEDA H. Accumulation and release of nitrogen and phosphorus in relation to lignin decomposition in leaf litter of 14 tree species. Ecol. Res. 19, 593, 2004.
  • 17. CORTEZ J., DEMARD J.M., BOTTNER P., JOCKTEUR MONROZIER L. Decomposition of Mediterranean leaf litters: a microcosm experiment investigating relationships between decomposition rates and litter quality. Soil Biol. Biochem. 28, 4/5, 443, 1996.
  • 18. BERG B., McCLAUGHERTY C. A. Nitrogen and phosphorus release from decomposing litter in relation to the disappearance of lignin. Can. J. Bot. 67, 1148,1989.
  • 19. PETERSON D.L., ROLFE G.L. Nutrient dynamics and decomposition of litterfall in floodplain and upland forests of Central Illinois. For. Sei. 28, (4), 667,1982.
  • 20. ŚWIETLIK J., SIKORSKA E. Characterization of natural organic matter fractions by high pressure size-exclusion chromatography, specific UV absorbance and total luminescence spectroscopy, Pol. J. Environ. Stud. 15, (1), 145, 2005.
  • 21. DĘBSKA B., DRAG M., BANACH-SZOTT M. Molecular size distribution and hydrophilic and hydrophobic properties of humic acids isolated from forest soil. Soil & Water Res. 2, (2), 45, 2007.
  • 22. WOELKI G., FRIEDRICH S., HANSCHMANN G., SALZER R. HPLC fractionation and structural dynamics of humic acids. Fresenius J. Anal. Chem. 357, 548,1997.
  • 23. PREUBE G„ FRIEDRICH S., SALZER R. Retention behaviour of humic substances in reversed phase HPLC. Fresenius J. Anal. Chem. 368, 268, 2000.
  • 24. DĘBSKA B. Properties of humic substances of soil fertilized with slurry. Ph.D. Thesis, UTA, Bydgoszcz, pp. 1-112, 2004 [In Polish],
  • 25. TOBIASOVA E. Transformation of plant residues in different soil types. Ph.D. Thesis, SAU Nitra, Slovakia, pp. 1-25, 2001.
  • 26. TORBERT H.A., POTTER K.N., MORRISON J.E. Tillage intensity and fertility level effects on nitrogen and carbon cycling in a vertisol. Commun. Soil Sei. Plant Anal. 28, 699, 1997.
  • 27. JURCOVA O., TOBIASOVA E., ZAUJEC A. Textural and hydrothermic conditions of soil environment as the factors limiting plant remains mineralization. Vedecké práce VÚPOP, Bratislava, Slovakia 2001.
  • 28. HOWARD P.J.A., HOWARD D.M., LOWE L.E. Effects of tree species and soil physico-chemical conditions on the nature of soil organic matter. Soil Biol. Biochem. 30, (3), 285,1998.
  • 29. RICE J., MacCARTHY P. Statistical evaluation of elemental composition of humic substances. Org. Gcochem. 17, 635,1991.
  • 30. ALBRECHT R., ZIARELLI F., ALARCON-GUTIERREZ E., LE PETIT J., TERROM G., PERISSOL C. 13C solid-state NMR assessment of decomposition pattern during co-composting of sewage sludge and green wastes. Europ. J. Soil Sei. 59, 445, 2008.
  • 31. ROSELL, R. A., ANDRRJLO A.E., SCHNITZER M., CRESPO M.B., MIGLIERINA A.M. Humic acids properties of an argiudoll soil under two tillage systems. Sei. Total Environ., 81/82, 391,1989.
  • 32. SANCHEZ-MONEDERO M.A., CEGARRA J., GARCIA D., ROIG A. Chemical and structural evolution of humic acids during organic waste composting. Biodegradation 13, 361, 2002.
  • 33. VARTIAINEN T., LIIMATAINEN A., KAURANEN P. The use of TSK size exclusion columns in determination of the quality and quantity of humus in raw waters and drinking waters. Sei. Total Environ. 62, 75, 1987.
  • 34. CONTE P., PICCOLO A. High pressure size exclusion chromatography (HPSEC) of humic substances: molecular sizes, analytical parameters, and column performance. Chemosphere 38, 517,1998.
  • 35. NISSINEN T.K., MIETTINEN I.T., MARTIKAINEN P.J., VARTIAINEN T. Molecular size distribution of natural organic matter in raw and drinking waters. Chemosphere 45, 865, 2001.
  • 36. BELYAEVA E. Y., PERMINOVA I. V, KUDRYAVTSEV A. V., NOVIKOV A. P. Compension of non-exclusion effects during gel-permeation fractionation of humic substances, in Humic Substances - Linking Structure to Functions. F. H. Frimmel and G. Abbt-Braun, Eds., Karlsruhe, Germany, pp. 217-220, 2006.
  • 37. CONTE P., SPACCINI R., PICCOLO A. Advanced CPMAS- 13C NMR techniques for molecular characterization of size-separated fractions from a soil humic acid. Anal. Bioanal. Chem. 386, 382, 2006.
  • 38. PICCOLO A., CONTE P., TRIVELLONE E., VAN LAGEN B., BUURMAN P. Reduced heterogeneity of lignite humic acids by preparative HPSEC following interaction with an organic acid. Environ. Sci. Technol. 36, 76, 2002.
  • 39. CANELLAS L.P., PICCOLO A., DOBBSS L.B., SPACCINI R., OLIVARES F.L., ZANDONADI D.B., FACANHA A.R. Chemical composition and bioactivity properties of size-fractions separated from vermicompost humic acid. Chemosphere 78, 457, 2010.
  • 40. CERITINI G., AGNELLI A., CORTI G., CAPPERUCCI A. Composition and mean residence time of molecular weight fractions of organic matter extracted from two soils under different forest species. Biogeochemistry 71, 299, 2004.
  • 41. EGEBERG P., ALBERTS J.J. HPSEC as a prepative fractionation technique for studies of natural organic matter (NOM). Environ. Technol. 24, 309, 2003.
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