Carbon cycle implication

Steffen W, Noble I, Canadell J, Apps M, Schulze ED, Jarvis PG (1998) The terrestrial carbon cycle implication for the Kyoto protocol. Science 280 1393-1394... [Pg.256]

Still C. J., Berry J. A., CoIIatz G. J., and DeFries R. S. (2003) Global distribution of C3 and C4 vegetation carbon cycle implications. Global Biogeochem. Cycles 17(1) 10.1029/ 2001GB001807. [Pg.2123]

IGBP Terrestrial Carbon Working Group. (1998). The terre.strial carbon cycle Implications for the Kyoto Protocol. Science 280, 1393-1394. [Pg.198]

Tajika, E. 2003. Eaint young Sun and the carbon cycle, implications for the proterozoie global glaciations. Earth and Planetary Science Letter443-453. [Pg.298]

Lerman, A. Mackenzie, F.T. 2005. 0O2 air-sea exchange due to calcium carbonate and organic matter storage, and its implications for the global carbon cycle. Aquatic Geochemistry, 11, 345-390. [Pg.480]

Baker AJ, Fallick AE (1989) Heavy carbon in two-biUion-year-old marbles from Lofoten-Vesteralen, Norway implications for the Precambrian carbon cycle. Geochim Cosmochim Acta 53 1111-1115... [Pg.230]

Keeling, C. D and S. R. Shertz, Seasonal and Interannual Variations in Atmospheric Oxygen and Implications for the Global Carbon Cycle, Nature, 358, 723-727 (1992). [Pg.835]

NOx emissions are implicated in phenomena such as acidification and eutrophication, with their subsequent impacts on the biodiversity of habitats, as well as radiative forcing of climate through the formation of nitrate aerosol and tropospheric ozone, and impacts on the carbon cycle [3]. [Pg.32]

Kieber, D.J., J. McDaniel, and K. Mopper. 1989. Photochemical source of biological substrates in sea water Implications for carbon cycling. Nature 341, 637-639. [Pg.435]

Skoog, A., and R. Benner. 1997. Aldoses in various size fractions of marine organic matter Implications for carbon cycling. Limnology and Oceanography 42 1803—1813. [Pg.118]

Senum G.L. and Gaffney J.S. (1985) A reexamination of the tropospheric methane cycle Geophysical implications. In The Carbon Cycle and Atmospheric CO2 Natural variations Archean to Present (eds. E.T. Sundquist and W.S. Broecker), pp. 61-69. AGU Geophys. Monograph 32, Washington, D.C. [Pg.665]

Mitra, S., Bianchi, T.S., McKee, B.A., and Sutula, M. (2002) Black carbon from the Mississippi River quantities, sources, and potential implications for the global carbon cycle. Environ. Sci. Technol. 36, 2296-2302. [Pg.631]

Montoya, J.P. (1994) Nitrogen isotope fractionation in the modern ocean implications for the sedimentary record. In Carbon Cycling in the Glacial Ocean Constraints on the Ocean s Role in Global Change (Zahn, R., Pedersen, T.F., Kaminski, M.A., and Labeyrie, L., eds.), pp. 259-280, Springe, Berlin. [Pg.632]

Quay, P. D., D. O. Wilbur, J. E. Richey, J. I. Hedges, A. H. Devol, and L. A. Martinelli. 1992. "Carbon cycling in the Amazon River Implications from the composition of particulate and dissolved carbon." Limnology and Oceanography 37 857-871. [Pg.305]

Repeta, D. J., and Aluwihare, L. I. (2006). Radiocarbon analysis of neutral sugars in high molecular weight dissolved organic matter implications for carbon cycling. Limnology and Oceanography 51(2), 1045-1053. [Pg.139]

Reimers, C. E., Jahnke, R. A., and McCorkle, D. C. (1992). Carbon fluxes and burial rates over the continental slope off California with implications for the global carbon cycle. Global Biogeochem. Cycles. 6, 199-224. [Pg.299]

Varekamp J. C., Kreulen R., Poorter R. P. E., and Vanbergen M. J. (1992) Carbon sources in arc volcanism with implications for the carbon cycle. Terra Nova 4, 363—373. [Pg.1019]

Methane clathrate decomposition has been implicated in the Latest Paleocene Thermal Maximum (—55 Ma ago) by an extraordinary injection of isotopically light carbon into the carbon cycle (Dickens, 2000, 2001a) and in Quaternary interstadials as indicated by observations of isotopically light foraminifera in Santa Barbara Basin sediments (Kennett et al., 2000). Dickens (2001a) compares the functioning of the CH4 hydrate to a bacterially mediated capacitor. [Pg.1996]

Schidlowski M. and Aharon P. (1992) Carbon cycle and carbon isotopic record geochemical impact of life over 3.8 Ga of Earth history. In Early Organic Evolution Implications for Energy and Mineral Resources (eds. M. Schidlowski, S. Golubic, M. M. Kimberley, D. M. McKirdy, and P. A. Trudinger). Springer, Berlin, pp. 147-175. [Pg.2855]

Ransom B., Shea K. E., Burkett P. J., Bennett R. H., and Baerwald R. (1998b) Comparison of pelagic and nepheloid layer marine snow implications for carbon cycling. Mar. Geol. 150, 39-50. [Pg.3029]

Dmffel E. R. M. (1985) Detection of El Nino and decade timescale variations of sea surface temperature from banded coral records implications for the carbon dioxide cycle. In The Carbon Cycle and Atmospheric CO2 Natural Variations Archean to Present. American Geophysical Union, Washington, DC, pp. 111-122. [Pg.3233]

Duplessy J.-C., Shackleton N. J., Matthews R. K., Prell W., Ruddiman W. F., Caralp M., and Hendy C. H. (1984) C record of benthic foraminifera in the last interglacial ocean implications for the carbon cycle and the global deep water circulation. Quat. Res. 21, 225-243. [Pg.3295]

Goldstein S. J., Lea D. W., Chakraborty S., Kashgarian M., and Murrell M. T. (2001) Uranium-series and radiocarbon geochronology of deep-sea corals implications for Southern Ocean ventilation rates and the oceanic carbon cycle. Earth Planet. Sci. Lett. 193, 167-182. [Pg.3296]

Bekker A., Kaufman A. J., Karhu J. A., Beukes N. J., Swart Q. D., Coetzee E. E., and Eriksson K. A. (2001) Chemostratigraphy of the Paleoproterozic Duitschland Formation, South Africa implications for coupled climate change and carbon cycling. Am. J. Set 301, 261-285. [Pg.3462]

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