Carbon (Organic, Degradation)

• Aller, R. C., 1998. Mobile deltaic and continental shelf muds as suboxic, fluidized bed reactors. Marine Chemistry, 61, 143–155.

  Article  Google Scholar 

• Armstrong, R. A., Lee, C., Hedges, J. I., Honjo, S., and Wakeham, S. G., 2002. A new, mechanistic model for organic carbon fluxes in the ocean based on the quantitative association of POC with ballast minerals. Deep-Sea Research II, 49, 219–236.

  Google Scholar 

• Baldock, J. A., and Skjemstad, J. O., 2000. Role of the soil matrix and minerals in protecting natural organic materials against biological attack. Organic Geochemistry, 31, 697–710.

  Article  Google Scholar 

• Berner, R. A., 1989. Biogeochemical cycles of carbon and sulfur and their effect on atmospheric oxygen over Phanerozoic time. Palaeogeography, Palaeoclimatology, Palaeoecology, 75, 97–122.

  Article  Google Scholar 

• Berner, R. A., 2003. The long term carbon cycle, fossil fuels and atmospheric composition. Nature, 426, 323–326.

  Article  Google Scholar 

• Blair, J. M., Parmelee, R. W., and Lavelle, P., 1995. Influences of earthworms on biogeochemistry. In Hendrix, P. F. (ed.), Earthworm Ecology and Biogeography in North America. Boca Raton, FL: Lewis, pp. 128–154.

  Google Scholar 

• Blair, N. E., Leithold, E. L., Ford, S. T., Peeler, K. A., Holmes, J. C., and Perkey, D. W., 2003. The persistence of memory: the fate of ancient sedimentary organic carbon in a modern sedimentary system. Geochimica et Cosmochimica Acta, 67, 63–73.

  Article  Google Scholar 

• Bohlen, P. J., Pelletier, D. M., Groffman, P. M., Fahey, T. J., and Fisk, M. C., 2004. Influence of earthworm invasion on redistribution and retention of soil carbon and nitrogen in northern temperate forests. Ecosystems, 7, 13–27.

  Article  Google Scholar 

• Burdige, D. J., 2007. Preservation of organic matter in marine sediments: controls, mechanisms, and an imbalance in sediment organic carbon budgets? Chemistry Reviews, 107, 467–485.

  Article  Google Scholar 

• Canfield, D. E., 1994. Factors influencing organic carbon preservation in marine sediments. Chemical Geology, 114, 315–329.

  Article  Google Scholar 

• Cortez, J., 1998. Field decomposition of leaf litters: relationships between decomposition rates and soil moisture, soil temperature and earthworm activity. Soil Biology and Biochemistry, 30, 783–793.

  Article  Google Scholar 

• Derenne, S., and Largeau, C., 2001. A review of some important families of refractory macromolecules: composition, origin and fate in soils and sediments. Soil Science, 166, 833–847.

  Article  Google Scholar 

• D’Hondt, S., Jorgensen, B. B., Miller, D. J., Batzke, A., Blake, R., Cragg, B. A., Cypionka, H., Dickens, G. R., Ferdelman, T., Hinrichs, K. U., Holm, N. G., Mitterer, R., Spivack, A., Wang, G., Bekins, B., Engelen, B., Ford, K., Gettemy, G., Rutherford, S. D., Sass, H., Skilbeck, C. G., Aiello, I. W., Guerin, G., House, C. H., Inagaki, F., Meister, P., Naehr, T., Niitsuma, S., Parkes, R. J., Schippers, A., Smith, D. C., Teske, A., Wiegel, J., Padilla, C. N., and Acosta, J. L. S., 2004. Distributions of microbial activities in deep subseafloor sediments. Science, 306, 2216–2221.

  Article  Google Scholar 

• Field, C. B., Sarmiento, J., and Hales, B., 2007. The carbon cycle of North America in a global context. In King, A. W., Dilling, L., Zimmerman, G. P., Fairman, D. M., Houghton, R. A., Marland, G., Rose, A. Z., and Wilbanks, T. J. (eds.), The North American Carbon Budget and Implications for the Global Carbon Cycle. U.S. Climate Change Science Program, Synthesis and Assessment Product 2.2. Asheville, NC: National Oceanic and Atmospheric Administration, National Climatic Data Center, pp. 21–29.

  Google Scholar 

• Formolo, M. F., Martini, A. M., Petsch, S. T., Nüsslein, K., and Salacup, J., 2008. Hydrocarbon biodegradation in sedimentary rocks linked to atmospheric methane variation during deglaciation. Geology, 36, 139–142.

  Article  Google Scholar 

• Goni, M. A., Yunker, M. B., Macdonald, R. W., and Eglinton, T. I., 2005. The supply and preservation of ancient and modem components of organic carbon in the Canadian Beaufort Shelf of the Arctic Ocean. Marine Chemistry, 93, 53–73.

  Article  Google Scholar 

• Hartnett, H. E., Keil, R. G., Hedges, J. I., and Devol, A. H., 1998. Influence of oxygen exposure time on organic carbon preservation in continental margin sediments. Nature, 391, 572–574.

  Article  Google Scholar 

• Head, I., Jones, D. M., and Röling, W., 2006. Marine microorganisms make a meal of oil. Nature Reviews Microbiology, 4, 173–182.

  Article  Google Scholar 

• Head, I. M., Jones, D. M., and Larter, S. R., 2003. Biological activity in the deep subsurface and the origin of heavy oil. Nature, 426, 344–352.

  Article  Google Scholar 

• Hedges, J. I., and Keil, R. G., 1995. Sedimentary organic-matter preservation – an assessment and speculative synthesis. Marine Chemistry, 49, 81–115.

  Article  Google Scholar 

• Hedges, J. I., Baldock, J. A., Gelinas, Y., Lee, C., Peterson, M. L., and Wakeham, S., 2001. Evidence for non-selective preservation of organic matter in sinking marine sediments. Nature, 409, 801–804.

  Article  Google Scholar 

• Honjo, S., Manganini, S. J., Krishfield, R. A., and Francois, R., 2008. Particulate organic carbon fluxes to the ocean interior and factors controlling the biological pump: a synthesis of global sediment trap programs since 1983. Progress in Oceanography, 76, 217–285.

  Article  Google Scholar 

• Jones, D. M., Head, I. M., Gray, N. D., Adams, J. J., Rowan, A. K., Aitken, C. M., Bennett, B., Huang, H., Brown, A., Bowler, B. F. J., Oldenburg, T., Erdmann, M., and Larter, S. R., 2008. Crude-oil biodegradation via methanogenesis in subsurface petroleum reservoirs. Nature, 451, 176–181.

  Article  Google Scholar 

• Lee, C., Wakeham, S., and Arnosti, C., 2004. Particulate organic matter in the sea: the composition conundrum. Ambio, 33, 565–575.

  Google Scholar 

• Leithold, E. L., Blair, N. E., and Perkey, D. W., 2006. Geomorphologic controls on the age of particulate organic carbon from small mountainous and upland rivers. Global Biogeochemical Cycles, 20, GB3022, doi:10.1029/2005GB002677.

  Google Scholar 

• Longworth, B. E., Petsch, S. T., Raymond, P. A., and Bauer, J. E., 2007. Linking lithology and land use to sources of dissolved and particulate organic matter in headwaters of a temperatures, passive-margin river system. Geochimica et Cosmochimica Acta, 71, 4233–4250.

  Article  Google Scholar 

• Martens, C. S., Haddad, R. I., and Chanton, J. P., 1992. Organic matter accumulation, remineralization, and burial in an anoxic coastal sediment. In Whelan, J. K., and Farrington, J. W. (eds.), Productivity, Accumulation and Preservation of Organic Matter in Recent and Ancient Sediments. New York: Columbia University Press, p. 82.

  Google Scholar 

• Petsch, S. T., Berner, R. A., and Eglinton, T. I., 2000. A field study of the chemical weathering of ancient sedimentary organic matter. Organic Geochemistry, 31, 475–487.

  Article  Google Scholar 

• Petsch, S. T., Smernik, R. J., Eglinton, T. I., and Oades, J. M., 2001. A solid state ¹³C-NMR study of kerogen degradation during black shale weathering. Geochimica et Cosmochimica Acta, 65, 1867–1882.

  Article  Google Scholar 

• Sabine, C. L., Heiman, M., Artaxo, P., Bakker, D. C. E., Chen, C. T. A., Field, C. B., Gruber, N., LeQuéré, C., Prinn, R. G., Richey, J. E., Romero-Lankao, P., Sathaye, J. A., and Valentini, R., 2004. Current status and past trends of the carbon cycle. In Field, C. B., and Raupach, M. R. (eds.), The Global Carbon Cycle: Integrating Humans, Climate, and the Natural World. Washington, DC: Island Press, pp. 17–44.

  Google Scholar 

• Schmidt, M. W. I., and Noack, A. G., 2000. Black carbon in soils and sediments: analysis, distribution, implications and current challenges. Global Biogeochemical Cycles, 14, 777–793.

  Article  Google Scholar 

• Sheridan, C. C., Lee, C., Wakeham, S. G., and Bishop, J. K. B., 2002. Suspended particle organic composition and cycling in surface and midwaters of the equatorial pacific ocean. Deep-Sea Research I, 49, 1983–2008.

  Article  Google Scholar 

• Suess, E., 1980. Particulate organic carbon fluxes in the oceans – surface productivity and oxygen utilization. Nature, 288, 260–263.

  Article  Google Scholar 

• Van Mooy, B. A. S., Keil, R. G., and Devol, A. H., 2002. Impact of suboxia on sinking particulate organic carbon: enhanced carbon flux and preferential degradation of amino acids via denitrification. Geochimica et Cosmochimica Acta, 66, 457–465.

  Article  Google Scholar 

• Wakeham, S. G., Lee, C., Hedges, J. I., Hernes, P. J., and Peterson, M. L., 1997. Molecular indicators of diagenetic status in marine organic matter. Geochimica et Cosmochimica Acta, 61, 5363–5369.

  Article  Google Scholar 

• Wakeham, S. G., Lee, C., and Hedges, J. I., 2002. Composition and flux of particulate amino acids and chloropigments in equatorial pacific seawater and sediments. Deep-Sea Research I, 47, 1535–1568.

  Google Scholar 

• Waldron, P., Petsch, S. T., Martini, A. M., and Nüsslein, K., 2007. Archaeal community structure and metabolic activity across a salinity gradient within a methane-producing sedimentary basin. Applied and Environmental Microbiology, 73, 4171–4179.

  Article  Google Scholar 

• Wellsbury, P., Mather, I., and Parkes, R. J., 2002. Geomicrobiology of deep, low organic carbon sediments in the Woodlark Basin, Pacific Ocean. FEMS Microbiology Ecology, 42, 59–70.

  Article  Google Scholar 

Download references