Abstract
The expanding agriculture in the Brazilian savanna, the Cerrado, changes C and nutrient storages of the savanna ecosystems thereby affecting the global C budget and the sustainability of the local land use. We examined the biomass and the C, N, P, and S storages in above- and belowground biomass, in the organic layer, and in the top 2 m of the mineral soil (Anionic Acrustoxes) of three replicate plots of each of native Cerrado, Pinus caribaea Morelet plantations, productive and degraded Bracchiaria decumbens Stapf. pastures, and of conventional and no-tillage soybean cultivation. Aboveground biomass – in the cropping systems shortly before harvest – decreased in the order, Pinus (15 kg m−2) > Cerrado (2.3) > conventional tillage (1.9) > no tillage (1.5) > productive pasture (0.64) > degraded pasture (0.37) and belowground biomass in the order, Pinus (9.1) > Cerrado (3.0) > productive pasture (2.2) > degraded pasture (1.5) > conventional tillage (0.60) > no tillage (0.41). The aboveground biomass contained 1.1 (degraded pasture) to 19% (Pinus) of the total C storage, 0.3 (productive pasture, degraded pasture) to 3.5% of the total N storage, 0.3 (degraded pasture) to 2.1% (no tillage, conventional tillage) of the total P storage, and 0.3 (degraded pasture) to 3.7% (Pinus) of the total S storage of the ecosystems. Total C storage in the ecosystems was significantly larger in the Pinus stands (36 kg m−2) than in all other systems; differences among Cerrado (20), degraded pasture (19), productive pasture (20), no tillage (19), and conventional tillage (19) were small and not significant. All land-use systems had larger N (Pinus, 1.5; degraded pasture, 1.3; productive pasture, 1.4; no tillage, 1.4; conventional tillage, 1.4 kg m−2) and S storage (PI, 28; degraded pasture, 33; productive pasture, 34; no tillage, 36; conventional tillage, 38 g m−2) than the Cerrado (N, 1.2 kg; S, 26 g m−2). The P storages varied between 17 and 29 g m−2 and were not significantly different among the studied ecosystems. The N and S accumulations in the 12–20-year-old land-use systems were larger than the cumulative known fertilizer inputs indicating that there were unknown inputs possibly including the exploration of the deeper subsoil by deep-reaching roots and transfer of nutrients to the topsoil. Our results indicate that afforestation with Pinus trees has the potential to sequester large amounts of C while pasture degradation, no tillage, and conventional tillage tended to result in small C losses. Land use resulted in a marked accumulation of N and S relative to the Cerrado.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Arshad M A, Schnitzer M, Angers D A and Ripmeester J A 1990 Effects of till vs no-till on the quality of soil organic matter. Soil Biol. Biochem. 22, 595–599.
Batjes N H 1996 Total carbon and nitrogen in the soils of the world. Eur. J. Soil Sci. 47, 151–163.
Batjes N H and Dijkshoorn J A 1999 Carbon and nitrogen stocks in the soils of the Amazon region. Geoderma 89, 273–286.
Bernoux M, da Conceição Santana Carvalho M, Volkoff B and Cerri C 2002 Brazil's soil carbon stocks. Soil Sci. Soc. Am. J. 66, 888–896.
Blevins R L, Smith M S, Thomas G W and Frye W W 1983 Influence of conservation tillage on soil properties. J. Soil Water Conserv. 38, 301–305.
Cadisch G, Schunke R M and Giller K E 1994 Nitrogen cycling in a pure grass pasture and a grass-legume mixture on a red latosol in Brazil. Trop. Grasslands 28, 43–52.
Castro E A d and Kauffman J B 1998 Ecosystem structure in the Brazilian Cerrado: a vegetation gradient of aboveground biomass, root mass, and consumption by fire. J. Trop. Ecol. 14, 263–283.
Chapuis Lardy L, Brossard M, Lopes Assad M L and Laurent J-Y 2002 Carbon and phosphorus stocks of clayey Ferralsols in Cerrado native and agroecosystems, Brazil. Agric. Ecosys. Environ. 92, 147–158.
De Camargo P B, Trumbore S E, Martinelli L A, Davidson E A, Nepstad D C and Victoria R L 1999 Soil carbon dynamics in regrowing forest of eastern Amazonia. Glob. Change Biol. 5, 693–702.
Dick W A 1983 Organic carbon, nitrogen, and phosphorus concentrations and pH in soil profiles as affected by tillage intensity. Soil Sci. Soc. Am. J. 47, 102–107.
Drumond M A, de Barros N F, de Souza A L and da Silva A F 1997 Distribuição de biomassa e de nutrientes em diferentes coberturas florestais e pastagem na região do médio Rio Doce-MG. R. Árv., Viçosa-MG, Brazil, pp 187–199.
Espirito Santo C V 1995 Diagnóstico e avaliação de setor florestal brasileiro região Centro-Oeste: Anuário executivo. FUNATURA/ ITTO/IBAMA, Brasília-DF, Brazil. 59 pp.
Fisher M J, Rao I M, Ayarza M A, Lascano C E, Sanz J I, Thomas R J and Vera R R 1994 Carbon storage by introduced deep-rooted grasses in the South American savannas. Nature 371, 236–238.
Friesen D K, Rao I M, Thomas R J, Oberson A and Sanz J I 1997 Phosphorus acquisition and cycling in crop and pasture systems in low fertility tropical soils. Plant Soil 196, 289–294.
Goedert W J 1983 Management of the Cerrado soils in Brazil: a review. J. Soil Sci. 34, 405–428.
Goodland R 1971 A physiognomic analysis of the ‘Cerrado’ vegetation of central Brazil. Ecol. 59, 411–419.
Hartung J and Elpelt B 1989 Multivariate Statistik. Oldenbourg-Verlag, München. 815 pp.
Heinrichs H, Brumsack H-J, Loftfield N and König N 1986 Verbessertes Druckaufschluçsystem für biologische und anorganische Materialien. Z. Pflanzenernähr. Bodenk. 149, 350–353.
IBGE (Instituto Brasileiro de Geografía e Estatística) 2002 www.ibge.gov.br/ibge/estatistica/economia/pam/tabela1pam.shtm, 23/01/2002.
Kornelius E, Saueressig M G and Goedert W J 1978 Pastures establishment and management in the Cerrado of Brazil. In Pasture Production in Acid Soils of the Tropics. Eds. PA Sánchez and LE Tergas. pp. 147–175. Centro Internacional de Agricultura Tropical (CIAT), Cali, Colombia.
Kotto-Same J, Woomer P L, Appolinaire M and Louis Z 1997 Carbon dynamics in slash-and-burn agriculture and land use alternatives of the humid forest zone in Cameroon. Agric. Ecosys. Environ. 65, 245–256.
Lal R and Kimble J M 2000 Tropical ecosystems and the global C cycle. In Global Climate Change and Tropical Ecosystems. Eds. R Lal, JM Kimble and BA Stewart. pp. 3–32. Adv. Soil Sci., CRC Press, Boca Raton, FL.
Lilienfein J and Wilcke W 2003 Water and element input into native, agri-and silvicultural ecosystems of the Brazilian savanna. Biogeochemistry, in press.
Lilienfein J, Wilcke W, Ayarza M A, Lima S d C, Vilela L and Zech W 1999 Annual course of matric potential in differently used savanna Oxisols in Brazil. Soil Sci. Soc. Am. J. 63, 1778–1785.
Lilienfein J, Wilcke W, Ayarza M A, Vilela L, Lima, S d C and Zech W2000a Soil acidification in Pinus caribaea forests on Brazilian savanna Oxisols. For. Ecol. Manage. 128, 145–157.
Lilienfein J, Wilcke W, Ayarza M A, Vilela L, Lima S d C and Zech, W 2000b Chemical fractionation of phosphorus, sulphur, and molybdenum in Brazilian savannah Oxisols under different land use. Geoderma 96, 31–46.
Lilienfein J, Wilcke W, Thomas R, Vilela L, Lima S d C and Zech W 2001a Effects of Pinus caribaea plantations on the C, N, P, and S status of Brazilian savanna Oxisols. For. Ecol. Manage. 147, 171–182.
Lilienfein J, Wilcke W, Zimmermann R, Gerstberger P, Araújo G M and Zech W2001b Nutrient storage in soil and biomass of native Brazilian Cerrado. J. Plant Nutr. Soil Sci. 164, 487–495.
Lilienfein J, Wilcke W, Vilela L, Ayarza M A, Lima S d C and Zech W 2003 Productivity and soil fertility of pastures on Brazilian savanna Oxisols. Soil Sci. Soc. Am. J., in press.
Lopes A, Ayarza M A and Thomas R J 1999 Sistemas agropastoriles en las sabanas de América Latina tropical: lecciones del desarollo agrícola de los Cerrados de Brasil. In Sistemas agropastoriles en sabanas tropicales de América Latina. Eds. EP Guimaraes et al. pp. 9–30. Centro Internacional de Agricultura Tropical (CIAT), Cali, Colombia and Empresa Brasileira de Pesquisa Agropecuária (EMBRAPA), Brasília DF, Brazil.
Lugo A E, Brown S and Chapman J 1988 An analytical review of production rates and stemwood biomass of tropical forest plantations. For. Ecol. Manage. 23, 179–200.
Moraes J L, Cerri C C, Melillo J M, Kicklighter D, Neill C Skole D L and Steudler P A 1995 Soil carbon stocks of the Brazilian Amazon basin. Soil Sci. Soc. Am. J. 59, 244–247.
Nepstad, D C, Carvalho C R d, Davidson E A, Jipp P H, Lefebvre P A, Negreiros G H, Silva E D d, Stone T A, Trumbore S E and Vieira S 1994 The role of deep roots in the hydrological and carbon cycles of Amazonian forests and pastures. Nature 372, 666–669.
Proctor J 1987 Nutrient cycling in primary and old secondary rainforests. Appl. Geogr. 7, 135–152.
Rasiah V and Armour J D 2001 Nitrate accumulation under cropping in the Ferrosols of far north Queensland wet tropics. Austr. J. Soil Res. 39, 329–341.
Resck D V S, Vasconselos C A, Vilela L and Macedo M C M 2000 Impact of conversion of Brazilian Cerrados to cropland and pastureland on soil carbon pool and dynamics. In Global Climate Change and Tropical Ecosystems. Eds. R Lal, JM Kimble and BA Stewart. pp. 169–196. Adv. Soil Sci., CRC Press, Boca Raton, FL.
Rosa R, Lima S d C and Assunção W L 1991 Abordagem preliminar das condições climáticas de Uberlândia (MG). Soc. Nat. 3, 91–108.
San José J J and Montes R A 2001 Management effects on carbon stocks and fluxes across the Orinoco savannas. For. Ecol. Manage. 150, 293–311.
San José J J, Montes R A and M R Fariñas 1998 Carbon stocks and fluxes in a temporal scaling from a savanna to a semi-deciduous forest. For. Ecol. Manage. 105, 251–262.
Schroth G, Silva L F d, Seixas R, Teixeira W G, Macêdo J L V and Zech W 1999 Subsoil accumulation of mineral nitrogen under polyculture and monoculture, fallow, and primary forest in a ferralitic Amazonian upland soil. Agric. Ecosyst. Environ. 1467, 1–12.
Soil Survey Staff 1998 Keys to Soil Taxonomy, USDA-NRCSNSSC, Lincoln, NE, USA.
Solomon D, Fritzsche F, Tekalign M, Lehmann J and Zech W 2002 Soil organic matter composition in the subhumid Ethiopian Highlands as influenced by deforestation and agricultural management. Soil Sci. Soc. Am. J. 66, 68–82.
Statsoft 1995 STATISTICA for Windows 5.1. StatSoft GmbH, Lol and Nielsen, Hoheluftchaussee 112, D-20253 Hamburg, Germany.
Tiessen H, Feller C, Sampaio E V S B and Garin P 1998 Carbon sequestration and turnover in semiarid savannas and dry forest. Clim. Change 40, 150–117.
Vogt K A, Grier C C and Vogt D J 1986 Production, turnover, and nutrient dynamics of above-and belowground detritus of world forests. Adv. Ecol. Res. 15, 303–377.
Whittaker R H 1970 Communities and Ecosystems. Macmillan, New York. 158 p.
Wilcke W and Lilienfein J 2002 Biogeochemical consequences of the transformation of native Cerrado into Pinus caribaea plantations in Brazil. Plant Soil 238, 175–189.
Zeien H and Brümmer G W 1989 Chemische Extraktion zur Bestimmung von Schwermetallbindungsformen in Böden. Mitteilgn. Dtsch. Bodenkundl. Gesellsch. 59, 505–510.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Lilienfein, J., Wilcke, W. Element storage in native, agri-, and silvicultural ecosystems of the Brazilian savanna. Plant and Soil 254, 425–442 (2003). https://doi.org/10.1023/A:1025579932395
Issue Date:
DOI: https://doi.org/10.1023/A:1025579932395