How do Humic Substances Sequester Carbon?

References

1. Chen, Y.; Chefetz, B.; Adani, F.; Genevini, P.; Hadar, Y. Organic matter transformation during composting of municipal soild waste. In: The Role of Humic Substances in the Ecosytems and in Environmental Protection. Drozd, J.; Gonet, S. S.; Senesi, N.; Weber, J. (eds.). Wroclaw: Polish Society of Humic Substances, 1997, p. 795-804. See also Filip, Z. K., ibid. p 805-810.
   
   
2. Arslanov, K. A.; Gerasimov, I. P.; Zubkov, A. I.; Kozyreva, M. G.; Rubilin, E. V.; Chichagova, O. A. Determination of the age of chernozem using a radiocarbon method. Doklady Akademii Nauk SSSR 192: 1141-4 (1970).
   
   
3. Gerasimov, I. P.; Chichagova, O. A. Radiocarbon dating of soil humus.Pochvovedenie 10: 3-11 (1971).
   
   
4. Nemecek, J. Carbon-14 determination of the age of organic substances in chernozems.Rostlinna Vyroba 17: 745-51 (1971).
   
   
5. Tolchel'nikov, Yu. S.; Kostarev, A. S. Radiocarbon determination of the age of alpha-humus podzol.Izv. Vses. Geogr. Ova III: 264-8 (1979).
   
   
6. Matthews, J. A. Natural carbon-14 age /depth gradient in a buried soil.Naturwiss. 68: 472-4 (1981).
   
   
7. Schoute, J. F. T.; Griede, J. W.; Mook, W. G.; Roeleveld, W. Radiocarbon dating of vegetation horizons, illustrated by an example from the Holocene coastal plain in the northern Netherlands.Geologie en Mijnbouw 60: 453-9 (1981).
   
   
8. Schoute, J. F. T.; Mook, W. G.; Streurman, H. J. Radiocarbon dating of vegetation horizons: methods and preliminary results.PACT ( Athens, Greece) 8: 295-311 (1983).
   
   
9. Chichagova, O. A.; Cherkinskii, A.; Tolchelnikov, Y. S.; Inversions of the radiocarbon age of humus in profiles of contemporary soils. Doklady Akademii Nauk SSSR 275: 1176-86 (1984).
   
   
10. Yamada, Y. The characterization of humus accumulation in Andosols by carbon-14 dating.Nogyo Kankyo Gijutsu Kenkyusho Hokoku 3: 23-86 (1986).
    
    
11. Theng, B. K. G.; Tate, K. R.; Becker-Heidmann, P. Establishing the age, location, and identity of the inert soil organic matter of a Spodosol.Zeit. Pflanz. Boden. 155: 181-4 (1992).
    
    
12. Murphy, E. M.; Schramke, J. A.; Fredrickson, J. K.; Bledsoe, H. W.; Francis, A. J.; Sklarew, D. S.; Linehan, J. C. The influence of microbial activity and sedimentary organic carbon on the isotope geochemistry of the Middendorf aquifer.Water Resources Research 28: 723-40 (1992).
    
    
13. Skjemstad, J. O.; Janik, L. J.; Head, M. J.; McClure, S. G. High-energy ultraviolet photooxidation: a novel technique for studying physically protected organic matter in clay- and silt-sized aggregates.J. Soil Sci. 44: 485-99 (1993).
    
    
14. Tsutsuki, K.; Kondo, R.; Shiraishi, H.; Kuwatsuka, S. Composition of lignin-degradation products, lipids, and opal phytoliths in a peat profile accumulated since 32,000 years B.P. in central Japan.Soil Sci. Plant Nutrit., 39: 463-74 (1993).
    
    
15. Cherkinsky, A. E.; Brovkin, V. A. D ynamics of radiocarbon in soils.Radiocarbon 35: 363-7 (1993). See also Baldock, J. A.; Nelson, P. N. Soil organic matter. In: Handbook of Soil Science, Sumner, M. E. (ed.). Boca Raton: CRC Press, 1999, p. B-41.
    
    
16. Schnitzer, M.; Dinel, H.; Pare, T.; Schulten, H. –R.; Ozdoba, D. Some chemical and spectroscopic characteristics of six organic ores. In: Humic Substances: Structures, Models and Functions. Ghabbour, E. A.; Davies, G. (eds.) Cambridge: Royal Society of Chemistry, 2001, p. 315-328.
    
    
17. Alvarez, R.; Alconada, M.; Lavada, R. Sewage sludge effects on carbon dioxide: Carbon production from a desurfaced soil. Commun. Soil Sci. Plant Anal., 30: 1861-1866 (1999).
    
    
18. Fortun, C.; Fortun, A.; Almendros, G. The effect of organic materials and their humified fractions on the formation and stabilization of soil aggregates. Sci. Total Environ. 81/82: 561-568 (1989).
    
    
19. Lal, R. Offsetting China’s CO 2 emissions by soil carbon sequestration. Climatic Change 65: 263-275 (2004).
    
    
20. Grant, B; Smith, W. N.; Desjardins, R.; Lemke, R.; Li, C. Estimated N 2O and CO 2 emissions as influenced by agricultural practices in Canada. Climatic Change 65: 315-332 (2004).
    
    
21. Nabuurs, G. J.; Mohren, G. M. J. Modelling analysis of potential carbon sequestration in selected forest types. Can J. Forest Res., 25: 1157-1172 (1995).
    
    
22. Rastogi, M.; Singh, S.; Pathak, H. Emission of carbon dioxide from soil. Current Sci. 82: 510-517 (2002).
    
    
23. Paustian, K.; Six, J.; Elliott, E. T.; Hunt, H. W. Management options for reducing CO 2 emissions from agricultural soils. Biogeochem. 48: 147-163 (2000).
    
    
24. http://soils.usda.gov/sqi/concepts/soil_biology/soil_food_web.html (accessed October 5, 2007).