Abstract
Satellite measurements are used to quantify the atmospheric greenhouse effect, defined here as the infrared radiation energy trapped by atmospheric gases and clouds. The greenhouse effect is found to increase significantly with sea surface temperature. The rate of increase gives compelling evidence for the positive feedback between surface temperature, water vapour and the green-house effect; the magnitude of the feedback is consistent with that predicted by climate models. This study demonstrates an effective method for directly monitoring, from space, future changes in the greenhouse effect.
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References
Hansen, J. et al. Climate Processes and Climate Sensitivity (eds Hansen, J. & Takahashi, T.) 130–163 (Am. geophys. Un., Washington, DC, 1984).
Manabe, S. & Wetherald, R. T. J. atmos. Sci. 24, 241–259 (1967).
Cess, R. D. J. atmos. Sci. 33, 1831–1843 (1976).
Barkstrom, B. R. Bull. Am. met. Soc. 65, 1170–1185 (1984).
Ramanathan, V. et al. Science 243, 57–62 (1989).
Beuttner, K. J. K. & Kern, C. D. J. geophys. Res. 70, 1329–1337 (1965).
Reynolds, R. W. J. clim. 1, 75–86 (1988).
Dickinson, R. E. & Cicerone, R. J. Nature 319, 109–114 (1986).
Prabhakara, C., Short, D. A. & Vollmer, B. E. J. Clim. appl. Met. 24, 1311–1324 (1985).
Mitchell, J. F. B., Wilson, C. A. & Cunnington, W. M. Q. Jl R. met. Soc., 113, 293–322 (1987).
Stone, P. H. & Carlson, J. H. J. atmos. Sci. 36, 415–423 (1979).
Coakley, J. A. J. atmos. Sci. 34, 465–470 (1977).
Prabhakara, C. Chang, H. D. & Chang, A. T. C. J. appl. Met. 21, 59–68 (1982).
Stephens, G. J. Clim. (in the press).
Goody, R. M. Atmospheric Radiation Vol. 1 Ch. 9 (Oxford University Press, 1964).
Luther, F. M. World Climate Programme Vol. 93 (WM0, Geneva 1984).
Williamson, et al. NCAR Technical Note NCAR/TN-285 +STR (NCAR, Boulder, Colorado, 1987).
Kiehl, J. T. & Ramanathan, V. J. geophys. Res. (in the press).
Wetherald, R. T. & Manabe, S. J. atmos. Sci. 32, 2044–2059 (1975).
Gadgil, S., Joseph, P. V. & Joshi, N. V. Nature 312, 142–143 (1984).
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Raval, A., Ramanathan, V. Observational determination of the greenhouse effect. Nature 342, 758–761 (1989). https://doi.org/10.1038/342758a0
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DOI: https://doi.org/10.1038/342758a0
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