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Himalayan Forests: A Net Source of Carbon for the Atmosphere

Published online by Cambridge University Press:  24 August 2009

J.S. Singh ,
A.K. Tiwari  and
A.K. Saxena
J.S. Singh
Affiliation:
Professor of BotanyBanaras Hindu UniversityVaranasi 221005, India
A.K. Tiwari
Affiliation:
Department of BotanyKumaun UniversityNaini Tal 263002, India
A.K. Saxena
Affiliation:
Hill CampusG.B. Pant University of Agriculture & TechnologyRanichauri Tehri – Garhwal 249119, India.
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Abstract

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Type
Short Communications & Reports
Information
Environmental Conservation , Volume 12 , Issue 1 , Spring 1985 , pp. 67 - 69
Copyright
Copyright © Foundation for Environmental Conservation 1985

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References

REFERENCES

Adams, J.A.S., Mantovani, M.S.M. & Lundell, L.L. (1977). Wood versus fossil fuel as a source of excess carbon dioxide in the atmosphere: a preliminary report. Science, 196, pp. 54–6.CrossRefGoogle ScholarPubMed
Armentano, T.V. & Ralston, C.W. (1980). The role of temperate-zone forests in the global carbon cycle. Can. J. For. Res., 10, pp. 5360.CrossRefGoogle Scholar
Bolin, B. (1977). Changes of land biota and their importance for the carbon cycle. Science, 196, pp. 613–6.Google Scholar
Breuer, G. (1979). Can forest policy contribute to solving the CO2 problem? Environ. Int., 2, pp. 449–51.Google Scholar
Chan, Y.H. (1982). Storage and release of organic carbon in peninsular Malaysia. Intern. J. Env. Studies, 18, pp. 211–22.Google Scholar
Chaturvedi, O.P. & Singh, J.S. (1984). Potential biomass energy from all-aged Chir Pine forest of Kumaun Himalaya. Biomass, 5, pp. 161–5.CrossRefGoogle Scholar
Cooper, C.F. (1982). Carbon storage in managed forests. Can. J. For. Res., 13, pp. 155–66.CrossRefGoogle Scholar
Kawosa, M.A. (1984). The use of satellite imagery for the mapping of vegetation-oriented land-use and forest systems dynamics of the Himalayan countries. Veröffentl. der Naturforschenden Gesellschaft Emden, Vol. 1, xv + 138 pp., illustr.Google Scholar
Kellogg, W.W. (1982). Society, science, and climate change. Foreign Aff., 60, pp. 1,076109.CrossRefGoogle Scholar
Lugo, A.E. (1980). Are tropical forests sources or sinks of carbon? In The Role of Tropical Forests on the World Carbon Cycle (Eds Brown, S., Lugo, A.E. & Liegel, B.). US Dep. Energy, Washington, Conf.—800350 [not available for checking].Google Scholar
Mehra, M.S., Pathak, P.C. & Singh, J.S. (in press). Nutrient movement in litterfall and precipitation components for Central Himalayan forests. Ann. Bot.Google Scholar
Negi, K.S., Rawat, Y.S. & Singh, J.S. (1983). Estimation of biomass and nutrient storage in a Himalayan moist temperate forest. Can. J. For. Res., 13, pp. 1,18596.Google Scholar
Pandey, U. & Singh, J.S. (1981). A quantitative study of the forest floor, litterfall and nutrient return in an oak-conifer forest in Himalaya, II: Pattern of litterfall and nutrient return. Acta Oecologica (Oecologia Generalis), 2, pp. 8399.Google Scholar
Pandey, U. & Singh, J.S. (1984). Energy-flow relationships between agro- and forest ecosystems in Central Himalaya. Environmental Conservation, 11 (1), pp. 4553, 10 figs.CrossRefGoogle Scholar
Shah, S.L. (1982). Ecological degradation and future of agriculture in the Himalaya. Indian J. Agr. Econ., 37, pp. 122.Google Scholar
Sharpe, D.M. & Johnson, W.C. (1981). Land-use and carbon storage in Georgia forests. J. Environ. Manage., 12, pp. 221–33.Google Scholar
Singh, J.S. & Singh, S.P. (1984). An Integrated Ecological Study of Eastern Kumaun Himalaya with Emphasis on Natural Resources, Pt. II. Kumaun University, Naini Tal, India: 378 pp.Google Scholar
Singh, J.S., Rawat, Y.S. & Chaturvedi, O.P. (1984). Replacement of oak forests with pine in the Himalaya affects the nitrogen cycle. Nature (London), 311, pp. 54–6.Google Scholar
Tiwari, A.K. & Singh, J.S. (1984). Mapping forest biomass in India through aerial photographs and nondestructive field sampling. Applied. Geogr., 4, pp. 151–65.Google Scholar
Westlake, D.F. (1963). Comparisons of plant productivity. Biol. Rev., 38, pp. 385425.Google Scholar
Wong, C.S. (1978). Atmospheric input of carbon dioxide from burning wood. Science, 200, pp. 197–9.CrossRefGoogle ScholarPubMed
Woodwell, G.M., Whittaker, R.H., Reiners, W.A., Likens, G.E., Delwiche, G.C. & Botkin, D.B. (1978). The biota and the world carbon budget. Science, 199, pp. 141–6.Google Scholar