Skip to main content
  • Home
  • About
    • Submissions
    • Content
      • Research Integrity
      • Home
      • About
        • About The Journal
        • Editorial Team
        • Editorial Policies
        • Contact
      • Submissions
      • Content
        • Articles
        • Issue Archive
        • Collections
      • Research Integrity
      • Account
      Journal Name Logo

      Tellus A: Dynamic Meteorology and Oceanography

      Start Submission
      Become a Reviewer
      Press Logo
      Reading: Stochastic climate models: Part I. Theory
      • PDF (US English)XML (US English)
      • Share

      Original Research Papers

      Stochastic climate models: Part I. Theory

      Authors
      • K. Hasselmann

      Abstract

      A stochastic model of climate variability is considered in which slow changes of climate are explained as the integral response to continuous random excitation by short period “weather” isturbances. The coupled ocean-atmosphere-cryosphere-land system is divided into a rapidly varying “weather” system (essentially the atmosphere) and a slowly responding “climate” system (the ocean, cryosphere, land vegetation, etc.). In the usual Statistical Dynamical Model (SDM) only the average transport effects of the rapidly varying weather components are parameterised in the climate system. The resultant prognostic equations are deterministic, and climate variability can normally arise only through variable external conditions. The essential feature of stochastic climate models is that the non-averaged “weather” components are also retained. They appear formally as random forcing terms. The climate system, acting as an integrator of this short-period excitation, exhibits the same random-walk response characteristics as large particles interacting with an ensemble of much smaller particles in the analogous Brownian motion problem. The model predicts “red” variance spectra, in qualitative agreement with observations. The evolution of the climate probability distribution is described by a Fokker-Planck equation, in which the effect of the random weather excitation is represented by diffusion terms. Without stabilising feedback, the model predicts a continuous increase in climate variability, in analogy with the continuous, unbounded dispersion of particles in Brownian motion (or in a homogeneous turbulent fluid). Stabilising feedback yields a statistically stationary climate probability distribution. Feedback also results in a finite degree of climate predictability, but for a stationary climate the predictability is limited to maximal skill parameters of order 0.5.

      Year: 1976
      Volume: 28 Issue: 6
      Page/Article: 473-485
      DOI: 10.3402/tellusa.v28i6.11316
      Submitted on Jan 19, 1975
      Accepted on Apr 5, 1975
      Published on Jan 1, 1976
      Peer Reviewed
      CC BY 4.0

      References

      • Budyko , M. I . 1969 . The effect of solar radiation variations on the climate of the earth . Tellus 21 , 611 – 619 .  

      • Frankignoul , C. & Hasselmann , K . 1976 . Stochastic climate models. Part 2, Application to sea-sur-face temperature anomalies and thermocline variability (in preparation).  

      • GARP US Committee Report , 1975 . Understand-ing climate change . A programme for action. Nat. Acad. Sciences , Wash .  

      • GARP Publication 16, 1975. The physical basis of climate and climate modelling. World Met. Or-ganiz., Internat. Council Scient. Unions.  

      • Hasselmann , K . 1966 . Feynman diagrams and in-teraction rules of wave-wave scattering processes . Rev. Geophys . 4 , 1 – 32 .  

      • Hasselmann , K . 1967 . Non-linear interactions treat-ed by the methods of theoretical physics (with application to the generation of waves by wind) . Proc. Roy. Soc. A 299 , 77 – 100 .  

      • Hinze , J . 0. 1959. Turbulence. McGraw-Hill. Kadomtsev, B. B. 1965. Plasma turbulence. Aca-demic Press.  

      • King , J. W . 1975 . Sun-weather-relationships . Aero-nautics and Astronautics 13 , 10 – 19 .  

      • Lemke , P . 1976 . Stochastic climate models. Part 3, Application to zonally averaged energy models (in preparation).  

      • Lorenz , E. N . 1965 . A study of the predictability of a 28-variable atmospheric model . Tellus 17 , 321 – 333 .  

      • Lorenz , E. N . 1968 . Climate determinism . Meteor. Monographs 8 , 1 – 3 .  

      • Mitchell , J. M. , Jr . 1966 . Stochastic models of air-sea interaction and climatic fluctuation. (Symp. on the Arctic Heat Budget and Atmospheric Circulation, Lake Arrowhead, Calif., 1966.) Mem. RM-5233-NSF, The Rand Corp. , Santa Monica.  

      • Monin , A. S. & Vulis , I. L . 1971 . On the spectra of long-period oscillations of geophysical parameters . Tellus 23 , 337 – 345 .  

      • Sellers , W. D . 1969 . A global climate model based on the energy balance of the earth-atmosphere system . J. Appl. Met . 8 , 392 – 400 .  

      • Tatarski , V. I . 1961 . Wave propagation in a turbulent medium. McGraw-Hill.  

      • Taylor , G. I . 1921 . Diffusion by continuous move-ments . Proc. Lond. Math. Soc . 20 , 196 .  

      • Wang , M. C. & Uhlenbek , G. E . 1945 . On the theory of the Brownian motion . Rev. Mod. Phys . 17 , 323 – 342 .  

      • Wilcox , J. M . 1975 . Solar activity and the weather . J. Atmosph. Terrestr. Phys . 37 , 237 – 256 .  

      1. Abstract
      2. References
      • E-ISSN: 1600-0870
      • Published by Stockholm University Press
      • Terms and Conditions
      • Privacy Policy
      v.1.7.19