Abstract
The unique forest ecosystems investigated were created on the place of natural steppe biogeocoenoses 60 years ago. The aim of the study was to elucidate the effect of plant species on the formation of organic C and N stocks in soils and to estimate nitrogen availability for artificial wood plantation. For this purpose, 290 soil samples were taken from four forest monocultures (Quercus robur L., Pinus sylvestris L., Cotinus coggygria Scop., and Acer tataricum L.) and from virgin steppe ecosystem. The amounts and stocks of organic C, total and readily nitrified N, and seasonal dynamics of NO3 − and NH4 + ions activities were determined. It was shown that the species composition of the stands influenced the stock of organic C and N in soils. The storages of C and total N differed by 74 and 4.4 Mg/ha−1, respectively, in the litter and upper horizons (0–40-cm layer) in the stands studied. The differences in distribution of stocks of these elements in virgin steppe and artificial forest ecosystems were found. Organic C and N stocks increased 1.6–6.6 times in the forest litter compared to the steppe one, while in 5–40-cm layer, the storages of C and N decreased by 20–35% compared to the virgin soil. The impact of litter on total N content in arid climate was limited in 0–5-cm layer. The deficit of mineral N compounds was observed in autumn in soil with low stock of total N.
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Balboa-Murias MA, Rojo A, Álvarez JG, Merino AA (2006) Carbon and nutrient stock in mature Quercus robur L. stands in NW Spain. For Sci 63:557–565. doi:10.1051/forest:2006038
Bazilevich NI, Titlyanova AA (2008) Biotic turnover on five continents: element exchange processes in terrestrial natural ecosystems. Publishing house SB RAS, Novosibirsk (in Russian)
Berg B (2000) Litter decomposition and organic matter turnover in northern forest soils. For Ecol Manage 133(1–2):13–22. doi:10.1016/S0378-1127(99)00294 (Blackwell Publishing Ltd)
Borg B, McClaugherty Ch (2008) Plant litter. Springer, Berlin
Breusova AI (1984) Impact ecology of forest community of Northern Kazakhstan. Science, Leningrad (in Russian) (in Russian)
Cornelissen JH (1996) An experimental comparison of leaf decomposition rates in a wide range of temperate plant species and types. J Ecol 84:573–582
Díaz-Maroto IJ, Vila-Lameiro P (2006) Production and composition in natural stands of Quercus Robur L. Pol J Ecol 54(3):429–439
Ellert BH, Gregorich EG (1996) Storage of carbon, nitrogen and phosphorus in cultivated and adjacent forested soils of Ontario. Soil Sci 161(9):587–603
Gartzia-Bengoetxea N, González-Arias A, Merino A, Martínez de Arano I (2009) Soil organic matter in soil physical fractions in adjacent semi-natural and cultivated stands in temperate Atlantic forests. Soil Biol Biochem 41:1674–1683. doi:10.1016/j.soilbio.2009.05.010
Jandl R, Lindner M, Vesterdal L, Bauwens B, Baritz R, Hagedorn F, Johnson D, Minkkinen K, Byrne KA (2007) How strongly can forest management influence soil carbon sequestration? Geoderma 137:253–268
Johnson DW (1992) Effects of forest management on soil carbon storage. Water Air Soil Pollut 64:83–120
Karhu K, Wall A, Vanhala P, Liski J, Esala M, Regina K (2011) Effects of afforestation and deforestation on boreal soil carbon stocks—comparison of measured C stocks with Yasso07 model results. Geoderma 164:33–45
Kretinin MV, Kondrashov BV, Verchonov AV (1995) Landscapes: problems, properties, government and estimate. VNIALMI, Volgograd (in Russian)
Kulakova N (2010) Effect of silviculture amelioration on nutrient regime of meadow-chestnut soils in the Northern Caspian semiarid region. Agrochem 5:22–28 (in Russian)
Kurganova IN, Kudeyarov VN, Lopes de Gerenyu VO (2010) Updated estimate of carbon balance on Russian Territory. Tellus 62:497–505
Maestre FT, Cortina J (2004) Are Pinus halepensis plantations useful as a restoration tool in semiarid Mediterranean areas? For Ecol Mange 198:303–317. doi:10.1016/j.foreco.2004.05.040
Manzoni S, Porporato A (2007) A theoretical analysis of nonlinearities and feedbacks in soil carbon and nitrogen cycles. Soil Biol Biochem 39(7):1542–1556. doi:10.1016/j.soilbio.2007.01.006
Manzoni S, Jackson RB, Trofymow JA, Porporato A (2008) The global stoichiometry of litter nitrogen mineralization. Sci 321:684–686. doi:10.1126/science.1159792
Manzoni S, Trofymow JA, Jackson RB, Porporato A (2010) Stoichiometric controls on carbon, nitrogen, and phosphorus dynamics in decomposing litter. Ecol Monogr 80:89–106. doi:10.1890/09-0179.1
Martin A, Gallardo JF, Santa Regina I (1996) Long-term leaf decomposition in four oak forests located at the ‘Sierra de Gata’ mountains in Spain. In: Cbap CE et al (eds) Humic substances and organic matter in soil and water environments, IHSS—University of Minnesota. St Paul, USA, pp 119–130
McClaugherty C, Berg B (1987) Cellulose, lignin and nitrogen concentrations as rate regulating factors in late stages of forest litter decomposition. Pedobiol 30(2):101–112
Misik T, Kárász I (2010) Data to the changes in the structure of shrub layer in a hungarian oak-forest ecosystem. Agric Environ 2:45–57
Molchanov AA (1975) The biogeozenology approach to the oak-grove of forest-steppe. AS USSR. Sciences, Moscow (in Russian)
Nikitin SA (ed) (1966) Plantings and theirs water regime in chestnut soils zone. Sciences, Moscow (in Russian)
Olovyannikova IN (1985) Dynamics of vegetation cover productivity in Zavolgskay clay semi-desert. Botanicheskey J 89(7):1122 (in Russian)
Olovyannikova IN, Lindeman GV (2000) The cause of Ulmus pumila L. short life in the best conditions for growth in Cis-Caspian semi-desert. Lesovedenie 6:17–25 (in Russian)
Pausas J (1997) Litter fall and litter decomposition in Pinus sylvestris forests of the eastern Pyrenees. J Veg Sci 8:643–650
Perel’ TS (1979) Distribution and regularity earthworm’s allocation in fauna of USSR. Science, Moscow (in Russian)
Pérez-Bejarano A, Mataix-Solera J, Zornoza R, Guerrero C, Arcenegui V, Mataix-Beneyto J, Cano-Amat S (2010) Influence of plant species on physical, chemical and biological soil properties in a Mediterranean forest soil Cano-Amat. Eur J For Res 129:15–24. doi:10.1007/s10342-008-0246-2
Post WM, Kwon KC (2000) Soil carbon sequestration and land-use change: processes and potential. Glob Chang Biol 6:317–328
Prescott CE (2005) Do rates of litter decomposition tell us anything we really need to know? For Ecol Manage 220:66–74
Quideau SA, Chadwick OA, Bensi A, Graham RC, Anderson MA (2001) A direct link between forest vegetation type and soil organic matter composition. Geoderma 104:41–60. doi:10.1016/S0016-7061(01)00055-6
Rode AA, Pol’skiy MN (1960) Soils of the semidesert of North–Western Caspian region and their amelioration. Memoirs of Dokuchaev Soil Institute, vol 56. USSR Academy of Sciences, Moscow
Rodin LE, Bazilevich NI (1965) Dynamics of organic matter and biological cycle in main types of vegetation. Science, Leningrad
Rzheznikova NY, Bykov AV, Lindeman GV (1992) Zoogenic nitrogen transfer into artificial forest stands and its redistribution along the soil profile. Eurasian Soil Sci 9:79–86 (in Russian)
Sapanov MK (2003) Ecology of wood stands in arid regions. RAS, Institute of Forest Science, Moscow (in Russian)
Sariyildiz T, Anderson JM, Kucuk M (2005) Effects of tree species and topography on soil chemistry, litter quality, and decomposition in Northeast Turkey. Soil Biol Biochem 37:1695–1706
Shatalov V (2000) Floodplain Forests in the European Part of the Russian Federation. In: Klimo E et al (ed) The floodplain forests in Europe: current situation and perspectives. Boston; Koln: Brill European Forest Institute research report 10:185–201
Sizemskaya ML, Sapanov MK (2010) The modern conditions of ecosystems and strategy of adaptive nature management in northern Cis–Caspian semi-desert. Arid Ecosyst RAS 16(5):15–24 (in Russian)
Sokolov DF (1960) Decomposition and mineralization of oak and leaf fall under dry steppe conditions. Bulletin of Moscow society of natural scientists (Moskovskoe obshchestvo ispytatelej prirody). Department of Biology. LXV. 2:67–86 (in Russian)
Strickland MS, Osburn E, Lauber C, Fierer N, Bradford MA (2009) Litter quality is in the eye of the beholder: decomposition rates as a function of inoculum characteristics. Funct Ecol 23:627–636
Thomas KD, Prescott CE (2000) Nitrogen availability in forest floors of three tree species on the same site: the role of litter quality. Can J For Res 30(11):1698–1706. doi:10.1139/x00-101
Vorobiova LA (1988) Chemical analysis of soil. MSU, Moscow (in Russian)
Vsevolodova-Perel’ TS, Sizemskaya ML and Kolesnikov AV (2010) Changes in the specific composition and trophic structure of the soil population due to creation of artificial forest plantings in the Caspian semi–desert. Povolzhskiy Ecol J 2:142–150 (in Russian)
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This research was supported by Russian Foundation for Basic Researches (project no 09-04-00030).
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Communicated by A. Merino.
This article originates from the international symposium “Managed Forests in Future Landscapes. Implications for Water and Carbon Cycles (COST action FP 0601 FORMAN).”
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Kulakova, N. Impact of plant species on the formation of carbon and nitrogen stock in soils under semi-desert conditions. Eur J Forest Res 131, 1717–1726 (2012). https://doi.org/10.1007/s10342-012-0613-x
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DOI: https://doi.org/10.1007/s10342-012-0613-x