Three chapters: (1) Climate Prediction: The Limits of Ocean Models [by Stone]; (2) Complexities in the Climate System and Uncertainties in Forecasts [by Prinn]; (3) Modeling Human-Climate Interaction [by Jacoby]

Joint Program Reprint • Book/Chapter
Three chapters: (1) Climate Prediction: The Limits of Ocean Models [by Stone]; (2) Complexities in the Climate System and Uncertainties in Forecasts [by Prinn]; (3) Modeling Human-Climate Interaction [by Jacoby]
Stone, P.H.; Prinn, R.G.; Jacoby, H.D. (2004)
State of the Planet: Frontiers and Challenges in Geophysics, (R.S.J. Sparks and C.J. Hawksworth, editors), American Geophysical Union Monograph Vol. 150: Washington, DC, pp. 259-267; 297-305; 307-317

Abstract/Summary:

Stone chapter abstract: We identify three major areas of ignorance which limit predictability in current ocean GCMs. One is the very crude representation of subgrid-scale mixing processes. These processes are parameterized with coefficients whose values and variations in space and time are poorly known. A second problem derives from the fact that ocean models generally contain multiple equilibria and bifurcations, but there is no agreement as to where the current ocean sits with respect to the bifurcations. A third problem arises from the fact that ocean circulations are highly nonlinear, but only weakly dissipative, and therefore are potentially chaotic. The few studies that have looked at this kind of behavior have not answered fundamental questions, such as what are the major sources of error growth in model projections, and how large is the chaotic behavior relative to realistic changes in climate forcings. Advances in computers will help alleviate some of these problems, for example by making it more practical to explore to what extent the evolution of the oceans is chaotic. However models will have to rely on parameterizations of key small-scale processes such as diapycnal mixing for a long time. To make more immediate progress here requires the development of physically based prognostic parameterizations and coupling the mixing to its energy sources. Another possibly fruitful area of investigation is the use of paleoclimate data on changes in the ocean circulation to constrain more tightly the stability characteristics of the ocean circulation.

Prinn chapter abstract: The global atmosphere is a chemically complex and dynamic system, interacting both internally, mostly within the troposphere and stratosphere, and with the oceans, land, and living organisms. Its composition is changing today, and has also changed markedly over the last 400,000 years. Current understanding of this complex system resulting from recent observations, theory, and laboratory and modeling studies is reviewed. Also, results are presented from the Integrated Global System Model (IGSM). This is a coupled model of economic development, atmospheric chemistry, climate dynamics and ecosystem processes that explores possible future changes in atmospheric composition and climate. The results of an uncertainty analysis involving hundreds of runs of the IGSM imply that, without specific mitigation policies, the global average surface temperature may rise between 1.0 and 4.9 °C from 1990 to 2100 (95% confidence limits). Polar temperatures, absent policy, are projected to rise from about 1 to 12 °C (95% limits) with obvious great risk for high latitude ecosystems and ice sheets at the high end of this range. Analysis of the Kyoto Protocol, and a more stringent climate mitigation policy, shows the difficulties in accounting simply for the effects of other greenhouse gases relative to carbon dioxide. Also, the greatest effect of these policies is to lower the probability of extreme changes as opposed to lowering the medians.

Jacoby chapter abstract: If policymakers and the public are to be adequately informed about the climate change threat, climate modeling needs to include components far outside its conventional boundaries. An integration of climate chemistry and meteorology, oceanography, and terrestrial biology has been achieved over the past few decades. More recently the scope of these studies has been expanded to include the human systems that influence the planet, the social and ecological consequences of potential change, and the political processes that lead to attempts at mitigation and adaptation. For example, key issues—like the relative seriousness of climate change risk, the choice of long-term goals for policy, and the analysis of today's decisions when uncertainty may be reduced tomorrow—cannot be correctly understood without joint application of the natural science of the climate system and social and behavioral science aspects of human response. Though integration efforts have made significant contributions to understanding of the climate issue, daunting intellectual and institutional barriers stand in the way of needed progress. Deciding appropriate policies will be a continuing task over the long term, however, efforts to extend the boundaries of climate modeling and assessment merit long-term attention as well. Components of the effort include development of a variety of approaches to analysis, the maintenance of a clear division between close-in decision support and science/policy research, and the development of funding institutions that can sustain integrated research over the long haul.

© 2004 International Union of Geodesy and Geophysics and the American Geophysical Union

Book summary on publisher's website

Citation:

Stone, P.H.; Prinn, R.G.; Jacoby, H.D. (2004): Three chapters: (1) Climate Prediction: The Limits of Ocean Models [by Stone]; (2) Complexities in the Climate System and Uncertainties in Forecasts [by Prinn]; (3) Modeling Human-Climate Interaction [by Jacoby]. State of the Planet: Frontiers and Challenges in Geophysics, (R.S.J. Sparks and C.J. Hawksworth, editors), American Geophysical Union Monograph Vol. 150: Washington, DC, pp. 259-267; 297-305; 307-317 (http://globalchange.mit.edu/publication/14637)

Supersedes:

Reprint 2004-10. Three chapters: (1) Climate Prediction: The Limits of Ocean Models [by Stone]; (2) Complexities in the Climate System and Uncertainties in Forecasts [by Prinn]; (3) Modeling Human-Climate Interaction [by Jacoby] (State of the Planet: Frontiers and Challenges in Geophysics, 2004)

Superseded by:

Reprint 2004-10. Three chapters: (1) Climate Prediction: The Limits of Ocean Models [by Stone]; (2) Complexities in the Climate System and Uncertainties in Forecasts [by Prinn]; (3) Modeling Human-Climate Interaction [by Jacoby] (State of the Planet: Frontiers and Challenges in Geophysics, 2004)
  • Joint Program Reprint
  • Book/Chapter
Three chapters: (1) Climate Prediction: The Limits of Ocean Models [by Stone]; (2) Complexities in the Climate System and Uncertainties in Forecasts [by Prinn]; (3) Modeling Human-Climate Interaction [by Jacoby]

Stone, P.H.; Prinn, R.G.; Jacoby, H.D.

State of the Planet: Frontiers and Challenges in Geophysics
2004-10
(R.S.J. Sparks and C.J. Hawksworth, editors), American Geophysical Union Monograph Vol. 150: Washington, DC, pp. 259-267; 297-305; 307-317

Abstract/Summary: 

Stone chapter abstract: We identify three major areas of ignorance which limit predictability in current ocean GCMs. One is the very crude representation of subgrid-scale mixing processes. These processes are parameterized with coefficients whose values and variations in space and time are poorly known. A second problem derives from the fact that ocean models generally contain multiple equilibria and bifurcations, but there is no agreement as to where the current ocean sits with respect to the bifurcations. A third problem arises from the fact that ocean circulations are highly nonlinear, but only weakly dissipative, and therefore are potentially chaotic. The few studies that have looked at this kind of behavior have not answered fundamental questions, such as what are the major sources of error growth in model projections, and how large is the chaotic behavior relative to realistic changes in climate forcings. Advances in computers will help alleviate some of these problems, for example by making it more practical to explore to what extent the evolution of the oceans is chaotic. However models will have to rely on parameterizations of key small-scale processes such as diapycnal mixing for a long time. To make more immediate progress here requires the development of physically based prognostic parameterizations and coupling the mixing to its energy sources. Another possibly fruitful area of investigation is the use of paleoclimate data on changes in the ocean circulation to constrain more tightly the stability characteristics of the ocean circulation.

Prinn chapter abstract: The global atmosphere is a chemically complex and dynamic system, interacting both internally, mostly within the troposphere and stratosphere, and with the oceans, land, and living organisms. Its composition is changing today, and has also changed markedly over the last 400,000 years. Current understanding of this complex system resulting from recent observations, theory, and laboratory and modeling studies is reviewed. Also, results are presented from the Integrated Global System Model (IGSM). This is a coupled model of economic development, atmospheric chemistry, climate dynamics and ecosystem processes that explores possible future changes in atmospheric composition and climate. The results of an uncertainty analysis involving hundreds of runs of the IGSM imply that, without specific mitigation policies, the global average surface temperature may rise between 1.0 and 4.9 °C from 1990 to 2100 (95% confidence limits). Polar temperatures, absent policy, are projected to rise from about 1 to 12 °C (95% limits) with obvious great risk for high latitude ecosystems and ice sheets at the high end of this range. Analysis of the Kyoto Protocol, and a more stringent climate mitigation policy, shows the difficulties in accounting simply for the effects of other greenhouse gases relative to carbon dioxide. Also, the greatest effect of these policies is to lower the probability of extreme changes as opposed to lowering the medians.

Jacoby chapter abstract: If policymakers and the public are to be adequately informed about the climate change threat, climate modeling needs to include components far outside its conventional boundaries. An integration of climate chemistry and meteorology, oceanography, and terrestrial biology has been achieved over the past few decades. More recently the scope of these studies has been expanded to include the human systems that influence the planet, the social and ecological consequences of potential change, and the political processes that lead to attempts at mitigation and adaptation. For example, key issues—like the relative seriousness of climate change risk, the choice of long-term goals for policy, and the analysis of today's decisions when uncertainty may be reduced tomorrow—cannot be correctly understood without joint application of the natural science of the climate system and social and behavioral science aspects of human response. Though integration efforts have made significant contributions to understanding of the climate issue, daunting intellectual and institutional barriers stand in the way of needed progress. Deciding appropriate policies will be a continuing task over the long term, however, efforts to extend the boundaries of climate modeling and assessment merit long-term attention as well. Components of the effort include development of a variety of approaches to analysis, the maintenance of a clear division between close-in decision support and science/policy research, and the development of funding institutions that can sustain integrated research over the long haul.

© 2004 International Union of Geodesy and Geophysics and the American Geophysical Union

Book summary on publisher's website

Supersedes: 

Three chapters: (1) Climate Prediction: The Limits of Ocean Models [by Stone]; (2) Complexities in the Climate System and Uncertainties in Forecasts [by Prinn]; (3) Modeling Human-Climate Interaction [by Jacoby]