Soil organic matter and sorption capacity under different soil management practices in a productive vineyard

References

• Balashov E, Buchkina N. 2011. Impact of short- and long-term agricultural use of chernozem on its quality indicators. Int Agrophys. 25:1–5.
   Web of Science ®Google Scholar
• Blair N, Faulkner RD, Till AR, Poulton PR. 2006. Long-term management impacts on soil C, N and physical fertility: part I: Broadbalk experiment. Soil Till Res. 91:30–38.
   Web of Science ®Google Scholar
• Blanco-Canqui H, Lal R. 2007. Soil structure and organic carbon relationships following 10 years of wheat straw management in no-till. Soil Tillage Res. 95:240–254.
   Web of Science ®Google Scholar
• Conteh A, Blair GJ, Lefroy RDB, Whitbread A. 1999. Labile organic carbon determined by permangante oxidation and its relationships to other measurements of soil organic carbon. Humic Subst Environ. 1:3–15.
   Google Scholar
• Dziadowiec H, Gonet SS. 1999a. Estimation of soil organic carbon by Tyurin’s method. Methodical guide-book for soil organic matter studies (in Polish). 120:7–8.
   Google Scholar
• Dziadowiec H, Gonet SS. 1999b. Estimation of fractional composition of soil humus by Kononova-Bielcikova’s method. Methodical guide-book for soil organic matter studies (in Polish). 120:31–34.
   Google Scholar
• Fecenko J, Ložek O. 2000. Nutrition and fertilization of field crops (in Slovak). Nitra: Slovak University of Agriculture.
   Google Scholar
• Fiala KJ, Kobza J, Matušková Ľ, Brečková V, Makovníková J, Barančíková G, Búrik V, Litavec T, Houšková B, Chromaničová A, et al. 1999. Valid methods of soil analyses. Partial monitoring system – Soil. Bratislava: Soil Science and Conservation Research Institute.
   Google Scholar
• Graham MH, Haynes RJ, Meyer JH. 2002. Soil organic matter content and quality: effects of fertilizer applications, burning and trash retention on a long-term sugarcane experiment in South Africa. Soil Biol Biochem. 34:93–102.
   Web of Science ®Google Scholar
• Hraško J, Červenka L, Facek Z, Komár J, Něměček J, Pospíšil J, Sirový V. 1962. Soil analyses (in Slovak). Bratislava: SVPL.
   Google Scholar
• Hütsch BW, Augustin J, Merbach W. 2002. Plant rhizodeposition – an important source for carbon turnover in soils. J Plant Nutr Soil Sci. 165:397–407.
   Web of Science ®Google Scholar
• IUSS Working Group WRB. 2006. World reference base for soil resources 2006. 2nd edition. World Soil Resources Reports No. 103. Rome: FAO.
   Google Scholar
• Kader MA, Sleutel S, Begum A, D’Haene K, Jegajeevagan K, De Nevel S. 2010. Soil organic matter fractionation as a tool for predicting nitrogen mineralization in silty arable soils. Soil Use Manage. 26:494–507.
   Web of Science ®Google Scholar
• Kladivko JE. 2001. Tillage systems and soil ecology. Soil Till Res. 61:61–76.
   Web of Science ®Google Scholar
• Körschens M. 2002. Importance of soil organic matter for biomass production and environment a review. Arch Acker-Pfl Boden. 48:89–94.
   Google Scholar
• Kuzyakov Y, Friedel JK, Stahr K. 2000. Review of mechanisms and quantification of priming effects. Soil Biol Biochem. 32:1485–1498.
   Web of Science ®Google Scholar
• Leinweber P, Schulten HR. 2002. Non-hydrolyzable forms of soil organic nitrogen: extractability and composition. J Plant Nutr Soil Sci. 163:433–439.
   Google Scholar
• Łoginow W, Wisniewski W, Gonet SS, Ciescinska B. 1987. Fractionation of organic carbon based on susceptibility to oxidation. Pol J Soil Sci. 20:47–52.
   Google Scholar
• Lorandi R. 2012. Evaluation of cation exchange capacity (CEC) in tropical soils using four different analytical methods. J Agric Sci. 4:278–289.
   Google Scholar
• Ložek O, Varga L. 2005. Effect of foliar application of humates and nitrogen on quantitative and qualitative parameters of winter wheat. In: Zaujec A, Bielek P, Gonet SS, editors. Humic substances in ecosystems 6. Bratislava: VÚPOP; p. 110–114.
   Google Scholar
• Neff JC, Townsend AR, Gleixner G, Lehman SJ, Turnbull J, Bowman WD. 2002. Variable effects of nitrogen additions on the stability and turnover of soil carbon. Nature. 419:915–917.
   PubMed Web of Science ®Google Scholar
• Orlov DS. 1974. Humus substances in soil (in Russian). Moskva: Lomonosov University.
   Google Scholar
• Paterson E, Hall JM, Rattray EAS, Griffiths BS, Ritz K, Killham K. 1997. Effect of elevated CO2 on rhizosphere carbon flow and soil microbial processes. Global Change Biol. 3:363–377.
   Web of Science ®Google Scholar
• Potter KN, Tolbert HA, Jones OR, Matocha JE, Morrison JE, Unger PW. 1998. Distribution and amount of soil organic C in long-term management systems in Texas. Soil Till Res. 47:309–321.
   Web of Science ®Google Scholar
• Reeves DW. 1997. The role of soil organic matter in maintaining soil quality in continuous cropping system. Soil Till Res. 43:131–167.
   Web of Science ®Google Scholar
• Schiff S, Aravena R, Trumbore SE, Hilton MJ, Elgood R, Dillon PJ. 1997. Export of DOC from forested catchements on the Precambrian Shield of Central Ontario: clues from 13C and 14C. Biogeochem. 36:43–65.
   Web of Science ®Google Scholar
• Šimanský V. 2013. Soil organic matter in water-stable aggregates under different soil management practices in a productive vineyard. Arch Agron Soil Sci. 59:1207–1214.
   Web of Science ®Google Scholar
• Šimanský V, Bajčan D, Ducsay L. 2013. The effect of organic matter on aggregation under different soil management practices in a vineyard in an extremely humid year. Catena. 101:108–113.
   Web of Science ®Google Scholar
• Šimanský V, Tobiašová E. 2010. Impact of tillage, fertilization and previous crop on chemical properties of Luvisol under barley farming system. J Cent Eur Agr. 11:245–254.
   Google Scholar
• Šimanský V, Tobiašová E, Chlpík J. 2008. Soil tillage and fertilization of Orthic Luvisol and their influence on chemical properties, soil structure stability and carbon distribution in water-stable macro-aggregates. Soil Till Res. 100:125–132.
   Web of Science ®Google Scholar
• Šimon T, Javůrek M, Mikanová O, Vach M. 2009. The influence of tillage systems on soil organic matter and soil hydrophobicity. Soil Till Res. 105:44–48.
   Web of Science ®Google Scholar
• Standford G, Smith SJ. 1978. Oxidative release of potentially mineralizable soil nitrogen by acid permanganate extraction. Soil Sci. 126:210–218.
   Web of Science ®Google Scholar
• Stevenson FJ. 1982. Humus chemistry, genesis, composition, reactions. New York, NY: John Wiley & Sons.
   Google Scholar
• Stevenson JF. 1994. Humus chemistry. New York, NY: John Wiley & Sons.
   Google Scholar
• Storch VH. 1995. Misuses of statistical analysis in climate research. In: Storch HV, Navarra A, editors. Analysis of climate variability: applications of statistical techniques. Berlin: Springer-Verlag; p. 11–26.
   Google Scholar
• Szombathová N. 2010. Chemical and physico-chemical properties of soil humus substances as an indicator of anthropogenic changes in ecosystems (Báb a Dolná Malanta localities) (in Slovak). Nitra: Slovak University of Agriculture.
   Google Scholar
• Thomas GA, Dalal RC, Standley J. 2007. No-till effects on organic matter, pH, cation exchange capacity and nutrient distribution in a Luvisol in the semi-arid subtropics. Soil Till Res. 94:295–304.
   Web of Science ®Google Scholar
• Uri V, Varik M, Aosaar J, Kanal A, Kukumägi M, Lőhmus K. 2012. Biomass production and carbon sequestration in a fertile silver birch (Betula pendula Roth) forest chronosequence. For Ecol Manage. 267:117–126.
   Web of Science ®Google Scholar