Response of the Météo-France climate model to changes in CO2 and sea surface temperature (original) (raw)
References
Betts AK, Harshvardhan (1987) Thermodynamic constraint on the cloud liquid water feedback in climate models. J Geophys Res 92(D7):8483–8485 Google Scholar
Bhumralkar CM (1975) Numerical experiments on the computation of ground surface temperature in an atmospheric general circulation model. J Appl Meteor 14:1246–1258 Google Scholar
Boer GJ, Arpe K, Blackburn M, Déqué M, Gates WL, Hart TL, Le Treut H, Roekner E, Sheinin DA, Simmonds I, Smith RNB, Tiakoda T, Wetherald RT, Williamson D (1992) Some results from an intercomparison of the climates simulated by 14 atmospheric general circulation models. J Geophys Res 97:12771–12786 Google Scholar
Bougeault P (1985) A simple parameterization of the large-scale effects of cumulus convection. Mon Weather Rev 113:2108–2121 Article Google Scholar
Bowman KP, Kruger AJ (1985) A global climatology of the total ozone from Nimbus 7 Total Ozone Mapping Spectrometer. J Geophys Res 90:7967–7976 Google Scholar
Brasseur G, Hitchman MH (1988) Stratospheric response to trace gas perturbations: changes in ozone and temperature distributions. Science 240:634–637 Google Scholar
Cariolle D, Déqué M (1986) Southern Hemisphere medium-scale waves and total ozone disturbances in a spectral general circulation model. J Geophys Res 91(D10):10825–10846 Google Scholar
Cariolle D, Lasserre-Bigorry A, Royer J-F, Geleyn J-F (1990) A GCM simulation of the springtime Antarctic ozone decrease and its impact on midlatitudes. J Geophys Res 95(D2):1883–1898 Google Scholar
Cess RD, Potter GL, Blanchet J-P, Boer GJ, Del Genio AD, Déqué M, Dymnikov, Galin V, Gates WL, Ghan SJ, Kiehl JT, Lacis AA, Le Treut H, Li Z-X, Liang X-Z, McAvaney BJ, Meleshko VP, Mitchell JFB, Morcrette J-J, Randall DA, Rikus L, Roekner E, Royer J-F, Schlese U, Scheinin DA, Slingo A, Sokolov AP, Taylor KE, Washington WM, Wetherald RT, Yagai I, Zhang M-H (1990) Intercomparison and interpretation of climate feedback processes in 19 general circulation models. J Geophys Res 95:16601–16615 Google Scholar
Cess RD, Potter GL, Zhang M-H, Blanchet J-P, Chalita S, Colman R, Dazlich DA, Del Genio AD, Dymnikov V, Galin V, Jerrett D, Keup E, Lacis AA, Le Treut H, Liang X-Z, Mahfouf J-F, McAvaney BJ, Meleshko VP, Mitchell JFB, Morcrette J-J, Norris PM, Randall DA, Rikus L, Roekner E, Royer J-F, Schlese U, Scheinin DA, Slingo JM, Sokolov AP, Taylor KE, Washington WM, Wetherald RT, Yagai I (1991) Intercomparison of snow-feedback as produced by 17 general circulation models. Science 253:888–892 Google Scholar
Cubasch U, Hasselmann K, Hock H, Maier-Reimer E, Mikalojewicz U, Santer BD, Sausen (1992) Time-dependent greenhouse warming computations with a coupled ocean-atmosphere model. Clim Dyn 8:55–69 Google Scholar
Deardorff JW (1977) A parameterization of the ground surface moisture content for use in atmospheric predictions models. J Appl Meteor 16:1182–1185 Google Scholar
Dumenil L, Todini E (1992) A rainfall-runoff scheme for use in the Hamburg climate model. Adv Theor Hydrol 1:129–157 Google Scholar
Gates WL (1992) AMIP: the atmospheric model intercomparison project. Bull Am Meteorol Soc 73:1962–1970 Article Google Scholar
Gates WL, Cook KH, Schlesinger ME (1981) Preliminary analysis of experiments on the climatic effects of increased CO2 with an atmospheric general circulation model and a climatological ocean. J Geophys Res 86:6385–6393 Google Scholar
Gates WL, Mitchell JFB, Boer GJ, Cubasch U, Meleshko VP (1992) Climate modelling, climate prediction and model validation. Climate change 1992: the supplementary report to the IPCC scientific assessment. Cambridge University Press, Cambridge, pp 103–133 Google Scholar
Geleyn J-F (1987) Use of a modified Richardson number for parameterizing the effect of shallow convection. J Meteorol Soc Japan, Special NWP Symposium Volume, pp 141–149
Geleyn J-F, Hollingworth A (1979) An economical analytical method for the computation of the interaction between scattering and line absorption of radiation. Beitr Phys Atmos 52:1–16 Google Scholar
Houghton JT, Jenkins GJ, Ephraums JJ (1990) Climate change. The IPCC scientific assessment. Cambridge University Press, Cambridge Google Scholar
Jaeger L (1976) Monatskarten des Niederschlags fur die ganze Erde. Tech Rep 18, Ber Deutsch Wetterdienstes 139
Labbé L (1991) Validation mutuelle de deux approches des calculs radiatifs pour la provision numérique. Tech Rep ENM, 42, Av. Coriolis, 31057 Toulouse Cedex, France
Legates DR, Willmott CJ (1990) Mean seasonal and spatial variability in gauge-corrected global precipitation. Int J Climatol 10:111–127 Google Scholar
Li Z-X, Le Trent H (1992) Cloud-radiation feedbacks in a general circulation model and their dependence on cloud modelling assumptions. Clim Dyn 7:133–139 Google Scholar
Louis JF, Tiedke M, Geleyn JF (1981) A short history of the operational PBL parameterization of the ECMWF. In: Workshop on planetary boundary layer. ECMWF, pp 59–79
Mahfouf J-F (1991) Etude du code radiatif du modèle EMERAUDE. Tech Rep 17, CNRM, Toulouse, France Google Scholar
Manabe S, Wetherald RT (1975) The effects of doubling the CO2 concentration on the climate of a general circulation model. J Atmos Sci 32:3–15 Google Scholar
Manabe S, Wetherald RT (1987) Large-scale changes of soil wetness induced by an increase in atmospheric carbon dioxide. J Atmos Sci 44:1211–1235 Google Scholar
Mitchell JFB (1983) The seasonal response of a general circulation model to changes in CO2 and sea surface temperature. Q J R Meteorol Soc 109:113–152 Google Scholar
Mitchell JFB, Ingram WJ (1992) Carbon dioxide and climate: mechanisms of changes in cloud. J Clim 5:5–21 Google Scholar
Mitchell JFB, Wilson CA, Cunnington WM (1987) On CO2 climate sensitivity and model dependence results. Q J R Meteorol Soc 113:293–322 Google Scholar
Pitari G, Palermi S, Visconti G, Prinn RG (1992) Ozone response to a CO2 doubling: results from a stratospheric general circulation model with heterogeneous chemistry. J Geophys Res 97(D5):5953–5962 Google Scholar
Planton S, Déqué M, Bellevaux C (1991) Validation of an annual cycle simulation with a T42-L20 GCM. Clim Dyn 5:189–200 Google Scholar
Ramanathan V (1981) The role of ocean-atmosphere interactions in the CO2 climate problem. J Atmos Sci 38:918–930 Google Scholar
Rind D, Suozzo R, Balachandran NK, Prather MJ (1990) Climate changes and the middle atmosphere. Part I: the doubled CO2 climate. J Atmos Sci 47(4):475–494 Google Scholar
Ritter B, Geleyn J-F (1992) A comprehensive radiation scheme for numerical weather prediction models with potential applications in climate simulations. Mon Weather Rev 120:303–325 Article Google Scholar
Royer J-F, Planton S, Déqué M (1990) A sensitivity experiment for the removal of Arctic sea ice with the French spectral general circulation model. Clim Dyn 5:1–17 Google Scholar
Sausen R, Barthel K, Hasselmann K (1988) Coupled ocean-atmosphere models with flux corrections. Clim Dyn 2:154–163 Google Scholar
Schmitt C, Randall DA (1991) Effects of surface temperature and clouds on the CO2 forcing. J Geophys Res 96(D5):9159–9168 Google Scholar
Stephenson DB, Held IM (1993) GCM response of northern winter stationary waves and stormtracks to increasing amounts of carbon dioxide. J Clim (in press)
Stouffer RJ, Manabe S, Bryan K (1989) Interhemispheric asymmetry in climate response to a gradual increase of atmospheric CO2. Nature 342:660–662 Google Scholar
Tiedke M (1984) The effect of penetrative cumulus convection on the large-scale flow in a general circulation model. Beitr Phys Atmos 57:216–239 Google Scholar
Wetherald RT, Manabe S (1988) Cloud feedback processes in a general circulation model. J Atmos Sci 45:1397–1415 Google Scholar
Wilson CA, Mitchell JFB (1987) A doubled CO2 climate sensitivity experiment with a global climate model including a simple ocean. J Geophys Res 92(D):13315–13343 Google Scholar