Role of a simplified hydrological cycle and clouds in regulating the climate–biota system of Daisyworld

References

• Ackland, G. 2004. Maximization principles and Daisyworld. J. Theor Biol. 227, 121–128.
   Web of Science ®Google Scholar
• Ackland, G., Clark, M. and Lenton, T. 2003. Catastrophic desert forma-tion in Daisyworld. J. Theor Biol. 223, 39–44.
   Web of Science ®Google Scholar
• Adams, B., Can, J., Lenton, T. and White, A. 2003. One-dimensional Daisyworld: spatial interactions and pattern formation. J. Theor Biol. 223, 505–513.
   Web of Science ®Google Scholar
• Andreae, M., Rosenfeld, D., Artaxo, P., Costa, A., Frank, G. and co-authors. 2004. Smoking rain clouds over the Amazon. Science 303, 1337–1342.
   Google Scholar
• Baldocchi, D. D., Krebs, T. and Lecrerc M. Y. 2004. ‘Wet/dry Daisy-world’: a conceptual tool for quantifying the spatial scaling of hetero-geneous landscapes and its impact on the subgrid variability of energy fluxes. Tellus 57B, 175–188.
   Google Scholar
• Barry, R. G. and Carleton, A. M. 2001. Synoptic and Dynamic Clima-tology. Routledge, London, 608 pp.
   Google Scholar
• Betts, R. 1999. Self-beneficial effects of vegetataion on climate in a ocean-atmospehre general circulation model. Geophys. Res. Lett. 26, 1457–1460.
   Web of Science ®Google Scholar
• Budyko, M. 1974. Climate and Life. Academic Press, New York. Chahine, M. 1992. The hydrological cycle and its influence on climate. Nature 359, 373–380.
   Google Scholar
• Charlson, R. J., Lovelock, J., Andreae, M.O. and Warren, S. G. 1987. Oceanic phytoplankton, atmospheric sulphur, cloud albedo and cli-mate. Nature 326, 655–661.
   Google Scholar
• Chu, S. and Ledley, T. 1995. Hydrologic cycle parameterizations for energy balance climate models. J. Geophys. Res. 100, 16289-16 304.
   Google Scholar
• Claeys, M., Graham, B., Vas, G., Wang, W., Vermeylen, R. and co-authors. 2004. Formation of secondary organic aerosols through photooxidation of isoprene. Science 303, 1173–1176.
   Google Scholar
• Cohen, J. and Rich, A. 2000. Interspecific competition affects tempera-ture stability in Daisyworld. Tellus 52B, 980–984.
   Google Scholar
• Downing, K. and Zvirinsky, P. 1999. The simulated evolution of bio-chemical guilds: reconciling Gaia theory and natural selection. A rtific. Life 5,291–318.
   Google Scholar
• Fu, Q. 2003. Cloud-radiative processes. In: Encyclopedia of Atmospheric Sciences (eds. J. R. Holton, J. A. Curry, and J. A. Pyle). Elsevier Sciences, London, 1871–1874.
   Google Scholar
• Ghil, M. 2002. Natural climate variability. In: Encyclopedia of global environmental change Volume 1 (eds. T. Munn, M. MacCraken and J. Perry) John Wiley and Sons, Chichester, 544–549.
   Google Scholar
• Gorshkov, V. G., Gorshkov, V. V. and Makarieva, A. M. 2000. Biotic Regulation of the Environment. Springer, London.
   Google Scholar
• Gorshkov, V. G., Malcarieva, A. M. and Gorshkov, V. V. 2004. Revis-ing the fundamentals of ecological knowledge: the biota-environment interaction. EcoL Complex. 1, 17–36
   Web of Science ®Google Scholar
• Harding, S. and Lovelock, J. 1996. Exploiter-mediated coexistence and frecuency-dependant selection in a numerical model of biodiversity. J. Theor Biol. 182, 109–116.
   Web of Science ®Google Scholar
• Hartmann, D. 1994. Global Physical Climatology. Academic Press, New York, 411 pp.
   Google Scholar
• Hutjes, R., Kabat, P., Running, S., Shuttleworth, W., Field, C. and co-authors. 1998. Biospheric aspects of the hydrological cycle. J. Hy-droL 212-213, 1–21.
   Google Scholar
• Jarcourt, S. and Raymond, W. 1992. Comments on ‘Chaos in Daisy-world’ by X. Zeng et al. Tellus 44B, 243–246.
   Google Scholar
• Kirchner, J. 2002. The Gaia Hypothesis: fact, theory and wishful think-ing. Climat. Change 52, 391–408.
   Web of Science ®Google Scholar
• Kirchner, J. 2003. The Gaia Hypothesis: conjectures and refutations. Climat Change 58, 21–45.
   Web of Science ®Google Scholar
• Kleidon, A. 2004. Beyond Gaia: thermodynamics of life and Earth sys-tem functioning. J. Climat. Change 66, 271–319.
   Web of Science ®Google Scholar
• Kleidon, A. and K. Fraedrich 2005. Biotic entropy production and global atmosphere-biosphere interactions. In: Non-equilibrium Ther-modynamics and the Production of Entropy (eds. A. Kleidon and R. Lorentz). Springer, Berlin, Germany, 173–189.
   Google Scholar
• Lenton, T. 1998. Gaia and natural selection. Nature 394,439-447. Lenton, T. 2002. Testing Gaia: the effect of life on Earth's habitability and regulation. Climat. Change 52,409–422.
   Google Scholar
• Lenton, T. 2004. Clarifying Gaia: regulation with or without natural selection. In: Scientists Debate Gaia (eds. K. Schneider, J. Miller, E. Crist and P. Boston). MITPress, Boston, USA, 15–25.
   Google Scholar
• Lenton, T. and Lovelock, J. 2000. Daisyworld is Darwinian: constrains on adaptation are important for planetary self-regulation. J. Theor Biol. 206, 109–114.
   Web of Science ®Google Scholar
• Lenton, T. and Lovelock, J. 2001. Daisyworld revisited: quantifying biological effects on planetary self-regulation. Tellus 53B, 288–305.
   Google Scholar
• Lenton, T. and Wilkinson, D. 2003. Developing the Gaia theory: a re-sponse to the criticisms of Kirchner and Volk. Climat. Change 58, 1–12.
   Web of Science ®Google Scholar
• Lovelock, J. 2003. The living Earth. Nature 426, 769–770.
   PubMed Web of Science ®Google Scholar
• Malcarieva, J. and Gorshkov, A. 2007. Biotic pump of atmospheric mois-ture as driver of the hydrological cycle on land. Hydrol. Earth Sys. Sci. Discuss. 3, 1–53.
   Google Scholar
• Marzeion, B. and Timmermann, A. 2005. Biophysical feedbacks in the tropical Pacific. J. Climate 18, 58–70.
   Web of Science ®Google Scholar
• Meslchidze, N. and Nenes, A. 2006. Phytoplancton and cloudiness in the Southern Ocean. Science 314, 1419–1423.
   Web of Science ®Google Scholar
• Miller, J. and Rusell, G. 2004. Modeling feedbacks between water and vegetation in the north African climate system. In: Scientists Debate Gaia, (eds. K. Schneider, J. Miller, E. Crist and P. Boston), MITPress, Boston, USA, 297–305.
   Google Scholar
• Nevison, C., Gupta, V. and Klinger, L. 1999. Self-sustained temperature oscillations on Daisyworld. Tellus 51B, 806–814.
   Google Scholar
• Nordstrom, K., Gupta, V. and Chase, T. 2005. Role of the hydrological cycle in regulating the planetary climate system of a simple nonlinear dynamical model. Nonlinear Process. Geophys. 12, 741–753.
   Web of Science ®Google Scholar
• Olff, H., Ritchie, M. and Prins, H. 2002. Global environmental controls of diversity in large herbivores. Nature 415, 901–904.
   PubMed Web of Science ®Google Scholar
• Pierrehumbert, R. 2002. The hydrologic cycle in deep-time climate prob-lems. Nature 419, 191–198.
   PubMed Web of Science ®Google Scholar
• Poveda, G. and Mesa, 2000. On the existence of Lloró (the rainiest locality on Earth): enhanced ocean-atmosphere-land interaction by a low-level jet. Geophys. Res. Lett. 27, 1675–1678.
   Web of Science ®Google Scholar
• Pujol, T. 2002. The consequence of maximum thermodynamic efficiency in Daisyworld. J. Theor Biol. 217, 53–60.
   Web of Science ®Google Scholar
• Ramanathan, V., Cess, R. D., Harrison, E. E, Minnis, P., Barlcstrom, B. R. and co-authors. 1989. Cloud radiative forcing and climate: results from the earth radiation budget experiment. Science 243, 57–63.
   Google Scholar
• Rangno, A. L. 2003. Clouds classification. In: Encyclopedia of Atmo-spheric Sciences (eds. J. R. Holton, J. A. Curry and J. A. Pyle). Elsevier Sciences, London, 467–475.
   Google Scholar
• Raval, A., and Ramanathan, V. 1989. Observational determination of the greenhouse effect. Nature 342, 758–761.
   Web of Science ®Google Scholar
• Robertson, D. and Robinson, J. 1998. Darwinian Daisyworld. J. Theor Biol. 195, 129–134.
   Google Scholar
• Saunders, P. 1994. Evolution without natural selection: further im-plications of the Daisyworld parable. J. Theor Biol. 166, 365–373.
   Google Scholar
• Seto, M. and Alcagi, T. 2005. Daisyworld inhabited with daisies in-corporating a seedsize/number trade-off: the mechanism of negative feedback on selection from a standpoint of the competition theory. J. Theor Biol. 234, 167–172.
   Web of Science ®Google Scholar
• Shaw, G. E. 1983. Bio-controlled thermostasis involving the sulfur cycle. ClimaL Change 5, 297–303.
   Web of Science ®Google Scholar
• Sole, R. V. and Bascompte, J. 2006. Self-Organization in Complex Ecosystems. Princeton University Press, Princeton.
   Google Scholar
• Stephens, G., Webster, P., Johnson, R., Engelen, R. and L'Ecuyer, T. 2004. Observational evidence for the mutual regulation of the tropical hydrological cycle and tropical sea surface temperatures. J. Climate 17, 2213–2224.
   Web of Science ®Google Scholar
• Stocker, S. 1995. Regarding mutations in Daisyworld models. J. Theor Biol. 175,495–501.
   Web of Science ®Google Scholar
• Sugimoto, T. 2002. Darwinian evolution does not rule out the Gaia Hypothesis. J. Theor Biol. 218, 447–455.
   Web of Science ®Google Scholar
• Szilder, K. and Lozowski, E. 1996. The influence of greenhouse warming on the atmospheric component of the hydrological cycle. HydroL Process. 10, 1317–1327.
   Web of Science ®Google Scholar
• Toniazzo, T., Lenton, T., Cox, P. and Gregory, J. 2005. Entropy and Gala: is there a link between MEP and self-regulation in the climate system?. In: Non-equilibrium Thermodynamics and the Production of Entropy (eds. A. Kleidon and R. Lorentz). Springer, Berlin, Germany, 224–241.
   Google Scholar
• Vallina, S. M. and Simó, R. 2007. Re-visiting the CLAW hypothesis. Environ. Chem. 4, 384–387.
   Web of Science ®Google Scholar
• Volk, T. 2002. Toward a future for Gaia theory. ClimaL Change 52, 423–430.
   Web of Science ®Google Scholar
• Volk, T. 2003. Natural selection, Gaia, and inadvertent by-products. Climat. Change 58, 1–2.
   Web of Science ®Google Scholar
• Volk, T. 2004. Gaia is life in a wasteworld of by-products. In: Scientists Debate Gaia (eds. K. Schneider, J. Miller, E. Crist and P. Boston), MIT Press, Boston, USA, 27–36.
   Google Scholar
• Von Bloh, W., Block, A. and Schellnhuber, H. 1997. Self-stabilization of the biosphere under global change: a tutorial geophysical approach. Tellus 49B, 249–262.
   Google Scholar
• Wang, W., Zhang, Q., Easterling, D. and Carl, T. 1993. Beijing cloudiness since 1875. J. Climate 6, 1921–1927.
   Web of Science ®Google Scholar
• Washington, W. 1995. Climate-model responses to increased CO2 and other greenhouse gases. In: Climate System Modeling (ed. K. Tren-berth). Cambridge University Press, Cambridge, UK, 643-668. Watson, A. and Lovelock, J.1983. Biological homeostasis of the global environment: the parable of Daisyworld. Tellus 35B, 284-289. Weber, S. 2001. On homeostasis in Daisyworld. ClimaL Change 48(2-3), 465–485.
   Google Scholar
• Weber, S. and Robinson, J. 2004. Daisyworld homeostasis and the Earth System. In: Scientists Debate Gaia (eds. K. Schneider, J. Miller, E. Crist and P. Boston), MIT Press, Boston, USA, 231–240.
   Google Scholar
• Wilkinson, D. 2004. Homeostatic Gaia: an ecologist's perspective on the possibility of regulation. In: Scientists Debate Gaia (eds. K. Schneider, J. Miller, E. Crist and P. Boston). MIT Press, Boston, USA, 71–76.
   Google Scholar
• Zeng, X., Pielke, R. and Eykholt, R. 1990. Chaos in Daisyworld. Tellus 42B, 309–318.
   Google Scholar
• Zeng, X., Pielke, R. and Eykholt, R. 1992. Reply to Jascourt and Raymond. Tellus 44B, 247–248.
   Google Scholar