Abstract
Organic carbon storage and turnover were altered in soils formed from volcanic ash (Andisols) as a result of conversion of tropical forest to pasture and sugarcane cropland. Changes in soil carbon storage after approximately a century of each land use were estimated using stable carbon isotope values and carbon contents. Total organic carbon stored in soils varied as a result of management, with pasture soils showing net carbon gain and sugarcane soils showing net carbon loss. In pasture soils, increases in carbon at depth (40 to 80 cm) are below the rooting zone of the introduced (C4) vegetation, and have stable carbon isotopic values indicative of forest (C3) plants. Within the pasture rooting zone (0–40 cm) the isotopic data reveals that additions of pasture (C4) organic matter have been offset by losses of C3 carbon. The concentration of Fe/Al oxides (soil minerals that bind with organic matter to form oxide-humus complexes) appear to control the quantity of carbon stored in soils, as well as the difference in the depth and magnitude of carbon storage changes that occur with each type of land use change. Sugarcane land use appears to induce dissociation of Fe/Al oxide-humus complexes and loss of oxide-associated organic matter from the profile. In pastures, Fe/Al oxide-humus complexes are translocated to deeper horizons in the soils, resulting in greater profile carbon storage and longer apparent turnover time of carbon stored below 50 cm depth. In this high precipitation region, carbon losses from the soil appear to occur via downward transport, either as colloids or in solution, in addition to the generally assumed pathway of flux to the atmosphere as CO2.
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References
Amundson R. and Baisden W.T. 1998. Stable isotope tracers in soil organic matter studies. In: Sala O.E., Mooney H., Howarth R.W. and Jackson R.B. (eds), Methods in Ecosystem Studies. Springer-Verlag, New York.
Anderson D.W. and Paul E.A. 1984. Organo-mineral complexes and their study by radiocarbon dating. Soil Sci. Soc. Am. J. 48: 298–301.
Balesdent J., Wagner G.H. and Mariotti A. 1988. Soil organic matter turnover in long-term field experiments as revealed by carbon-13 natural abundance. Soil Sci. Soc. Am. J. 52: 118–124.
Baskin M. and Binkley D. 1998. Changes in soil carbon following afforestation in Hawaii. Ecology 79: 828–833.
Boutton T.W. 1996. Stable carbon isotope ratios in soil organic matter and their use as indicators of climate change. In: Boutton T.W. and Yamasaki S.-I. (eds), Mass Spectrometry of Soils. Marcel Dekker, Inc., New York, pp. 47–82.
Camacho E., Robert M. and Jaunet A.M. 1988. Mineralogy and structural organization of a red to yellow soil sequence in Cuba-relationships with soil properties. In: Douglas L.A. (ed.), Soil Micromorphology: A Basic and Applied Science. Proceedings of the VIIIth International Working Meeting of Soil Micromorphology. Elsevier, Amsterdam, The Netherlands, pp. 183–190.
Clague D.A. and Hazlett R.W. 1989. Geological Field Guide to the Hawaiian Islands. American Geophysical Union, Washington, DC, USA.
Davidson E.A. and Ackerman I.L. 1993. Changes in soil carbon inventories following cultivation of previously untilled soils. Biogeochemistry 20: 181–193.
Delaney M., Brown S., Lugo A.E., Torres Lezama A. and Quintero N.B. 1997. The distribution of organic carbon in major-components of forests located in five life zones of Venezuela. Journal of Tropical Biology 13: 697–708.
Eswaran H., Van Den Berg E. and Reich P.F. 1993. Organic carbon in soils of the world. Soil Sci. Soc. Am. J. 57: 192–195.
Feigl B.J., Melillo J. and Cerri C.C. 1995. Changes in the origin and quality of soil organic matter after pasture introduction in Rondônia (Brazil). Plant and Soil 175: 21–29.
García-Oliva F., Cesar I., Morales P. and Maass J.M. 1994. Forest-to-pasture conversion influences on soil organic carbon dynamics in a tropical deciduous forest. Oecologia 99: 392–396.
Giambelluca T., Nullet D. and Schroeder T. 1986. Rainfall Atlas of Hawaii. Department of Land and Water Resources R76, State of Hawaii, USA.
Giambelluca T. and Sanderson M. 1993. The water balance and climate classification. In: Sanderson M. (ed.), Prevailing Trade Winds: Climate and Weather in Hawaii. University of Hawaii Press, Honolulu, pp. 56–72.
Houghton R.A., Hacker J.L. and Lawrence K.T. 1999. The U.S. carbon budget: contributions from land-use change. Science 285: 574–578.
Hu S., Coleman D.C., Carroll C.R., Hendrix P.F. and Beare M.H. 1997. Labile soil carbon pools in subtropical forest and agricultural ecosystems as influences by management practices and vegetation types. Agriculture, Ecosystems and Environment 65: 69–78.
Juvik J., Singelton D. and Clarke G. 1978. Climate and water balance on the island of Hawaii. In: Miller J.E. (ed.), Mauna Loa Observatory, a 20th Anniversary Report. National Oceanographic and Space Administration, Silver Spring, MD, USA, pp. 129–139.
Kononova M.M. and Bel'chikova N.P. 1970. Use of sodium pyrophosphate to separate and characterize organoiron and organoaluminum compounds in soil. Sov. Soil Sci. 6: 351–365.
Krishnaswamy J. and Richter D.D. 2002. Properties of advanced weathering-stage soils in tropical forests and pastures. Soil Sci. Soc. Am. J. 66: 244–253.
Lugo A.E., Sanchez P.A. and Brown S. 1986. Land use and organic carbon content of some subtropical soils. Plant and Soil 96: 185–196.
Martin J.P. and Haider K. 1986. Influence of mineral colloids on turnover rates of soil organic carbon. In: Huang P.M. and Schnitzer M. (eds), Interactions of Soil Minerals With Natural Organics. Soil Science Society of America, Madison, Wisconsin, USA, pp. 283–304.
Moraes J.F.L., Volkoff B., Cerri C.C. and Bernoux M. 1996. Soil properties under Amazon forest and changes due to pasture installation in Rondônia, Brazil. Geoderma 70: 63–81.
Nanzyo M., Dahlgren R. and Shoji S. 1993. Chemical characteristics of volcanic ash soils. In: Shoji S., Nanzyo M. and Dahlgren R. (eds), Volcanic Ash Soils: Genesis, Properties and Utilization. Elsevier, Amsterdam, pp. 145–187.
NOAA 1976. Bicentennial Guide: Climate of Hawaii. National Oceanic and Atmospheric Administration, Washington, DC, USA.
NRCS 1996. Keys to Soil Taxonomy. 6th edn. Pocahantas Press Inc., Blacksburg, VA, USA.
Nullet D. and Sanderson M. 1993. Radiation, energy balance and temperature. In: Sanderson M. (ed.), Prevailing Trade Winds: Climate and Weather in Hawaii. University of Hawaii Press, Honolulu.
Osher L.J. Transformations of weakly crystalline soil minerals in volcanic ash soils as a result of land use change. (in review).
Parfitt R., Theng B., Whitton J. and Shepherd T. 1997. Effects of clay minerals and land use on organic matter pools. Geoderma 75: 1–12.
Parfitt R.L., Parshotam A. and Salt G.J. 2002. Carbon turnover in two soils with contrasting mineralogy under long-term maize and pasture. Australian Journal of Soil Research 40: 127–136.
Paustian K., Andrén O., Janzen H.H., Lal R., Smith P., Tian G. et al. 1997. Agricultural soils as a sink to mitigate CO2 emissions. Soil Use and Management 13: 230–244.
Reiners W.A., Bouman A.F., Parson W.F.J. and Keller M. 1994. Tropical rain forest conversion to pasture – changes in vegetation and soil properties. Ecological Applications 4: 363–367.
Rhoades C.C. 1997. Soil Carbon and Nitrogen Changes following conversion of Ecuadorian Lower Montane Forest to Pasture. University of Georgia.
Schlesinger W.H. 1997. Biogeochemistry: An Analysis of Global Change. 2nd edn. Academic Press, San Diego, CA.
Schlesinger W.H. 1984. Soil organic matter: a source of atmospheric CO2. In: Woodwell G.M. (ed.), The Role of Terrestrial Vegetation in the Global Carbon Cycles: Measurement by Remote Sensing. John Wiley & Sons, New York, pp. 111–127.
Schwertmann U. 1988. Occurrence and formation of iron oxides in various pedoenvironments. In: Stucki J.W., Goodman B.A. and Schwertmann U. (eds), Iron in Soils and Clay Minerals. Reidel Publishing Company, Norwell, MA, USA, pp. 267–308.
SCS 1984. Soil survey laboratory methods and procedures for collecting soil samples. USDA-SCS, Washington, DC, USA.
Skjemstad J.O., Lefeuvre R.P. and Prebble R.E. 1990. Turnover of soil organic matter under pasture as determined by C-13 natural abundance. Aust. J. Soil Res. 28: 267–276.
Sollins P. and Radulovich R. 1988. Effects of soil physical structure on solute transport in a weathered tropical soil. Soil Sci. Soc. Am. J. 52: 1168–1173.
Solomon D., Fritzsche F., Lehmann J., Tekalign M. and Zech W. 2002. Soil organic matter dynamics in the subhumid agroecosystems of the Ethiopian Highlands: evidence from natural 13C abundance and particle-size fractionation. Soil Sci. Soc. Am. J. 66: 969–978.
Sorenson L.H. 1981. Carbon-nitrogen relationships during the humification of cellulose in soils containing different amounts of clay. Soil Biol. Biochem. 13: 313–321.
Sposito G. 1989. The Chemistry of Soils. Oxford University Press, New York.
Takahashi T., Fukuoka T. and Dahlgren R.A. 1995. Aluminum solubility and release rates from soil horizons dominated by aluminum-humus complexes. Soil Science and Plant Nutrition 41: 119–131.
Torn M.S., Trumbore S.E., Chadwick O.A., Vitousek P.M. and Hendricks D.M. 1997. Mineral control of soil organic carbon storage and turnover. Nature 389: 170–173.
Townsend A.R., Vitousek P.M. and Trumbore S.E. 1995. Soil organic matter dynamics along gradients in temperature and land-use on the island of Hawaii. Ecology 76: 721–733.
Trumbore S.E., Chadwick O.A. and Amundson R. 1996. Rapid exchange between soil carbon and atmospheric carbon dioxide. Science 272: 393–396.
Trumbore S.E., Davidson E.A., Camargo P.B., Nepstad D.C. and Martinelli L.A. 1995. Below ground cycling of carbon in forests and pastures of Eastern Amazonia. Glob. Biogeoch. Cyc. 9: 515–528.
Ugolini F.C. and Dahlgren R.A. 1991. Weathering environments and occurrence of imogolite/allophane in selected andisols and spodisols. Soil Sci. Soc. Am. J. 55: 1166–1171.
van Noordwijk M., Woomer P.L., Cerri P., Bernoux M. and Nugroho K. 1997. Soil carbon in the humid tropical forest zone. Geoderma 79: 187–225.
Veldkamp E. 1994. Organic carbon turnover in three tropical soils under pasture after deforestation. Soil Sci. Soc. Am. J. 58: 175–180.
White R.E. 1985. The influence of macropores on transport of dissolved and suspended matter through soil. Adv. Soil Sci. 3: 95–120.
Yoneyama T., Nakanishi Y., Morita A. and Liyanage B.C. 2001. ?13C values of organic carbon in cropland and forest soils in Japan. Soil. Sci. Plant Nutr. 47: 17–26.
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Osher, L.J., Matson, P.A. & Amundson, R. Effect of land use change on soil carbon in Hawaii. Biogeochemistry 65, 213–232 (2003). https://doi.org/10.1023/A:1026048612540
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DOI: https://doi.org/10.1023/A:1026048612540