Abstract Large discrepancies persist between projections of the physical impacts of climate change and economic damage estimates. These discrepancies increase with increasing global average temperature projections. Based on this observation, we recommend that in its Sixth Assessment Report (AR6), the Intergovernmental Panel on Climate Change (IPCC) improve its approach to the management of the uncertainties inherent in climate policy decisions. In particular, we suggest that the IPCC (1) strengthen its focus on applications of decision making under risk, uncertainty, and outright ambiguity and (2) estimate how the uncertainty itself affects its economic and financial cost estimates of climate damage and, ultimately, the optimal price for each ton of carbon dioxide released. Our hope is that by adopting these recommendations, AR6 will be able to resolve some of the documented inconsistencies in estimates of the physical and economic impacts of climate change and more effectively fulfill the IPCC’s mission to provide policymakers with a robust and rigorous approach for assessing the potential future risks of climate change. Introduction: An Opportunity to Improve Economic Estimates of Climate Impacts Preparations are under way for the Sixth Assessment Report (AR6) by the Intergovernmental Panel on Climate Change (IPCC), due to be released between 2021 and 2022. This Policy Brief argues that it is vitally important for AR6 to confront a major discrepancy between scientific and economic estimates of the impacts of unmanaged future climate change. In particular, we review mounting evidence that current economic models of the aggregate global impacts of climate change are inadequate in their treatment of uncertainty and grossly underestimate potential future risks. Inconsistent Assessment of Risks in the IPCC Fifth Assessment Report (AR5) The IPCC’s AR5 included a volume on impacts, adaptation, and vulnerability. This volume was produced by IPCC Working Group II (WGII) and included a chapter on “Emergent Risks and Key Vulnerabilities” (Oppenheimer et al. 2014). Counterintuitively, among five categories of concern, Oppenheimer et al. (2014) found that the risks associated with global aggregate impacts are the slowest to develop.1 These risks were estimated to be only moderate up to about 3.0°C of warming, although the other four categories show high risks. A major reason for the difference in risks discussed in Oppenheimer et al. (2014) is the inclusion of the results of a survey reported in a different AR5 WGII chapter (Arent et al. 2014), which appeared to show that economic impacts would be only “a small fraction of gross world product up until at least 2.5°C of warming above preindustrial” levels (Oppenheimer et al. 2014, p. 1078). However, Oppenheimer et al. (2014) also noted that published estimates of global economic impacts were “highly uncertain” and “omit a number of factors.” Many of these estimates were generated by climate–economy integrated assessment models (IAMs), which are also used to calculate the values of the social cost of carbon dioxide (SC-CO2) and the optimal CO2 price.2 There is now a growing awareness of the limitations of the existing generation of IAMs (e.g., National Academies of Sciences, Engineering, and Medicine 2017), including an understanding that they inadequately account for the potential damages from climate change, especially at moderate to high levels of warming (i.e., >2°C). These levels of warming have become increasingly likely (World Bank Group 2014). Although considerable econometric improvements have been made in estimating economic damages, including nonlinear effects (e.g., Burke, Hsiang, and Miguel 2015; Hsiang et al. 2017), these estimates largely ignore the potential for “tipping points” beyond which impacts accelerate, become unstoppable, or become irreversible (e.g., Lenton 2013; Kopp et al. 2016). Thus, in the remainder of this Policy Brief, we will argue that AR6 needs to go well beyond simply updating the damage functions in existing IAMs using the latest climate econometric evidence yet leaving the underlying IAM structure and decision framework unchanged. More specifically, we recommend that the IPCC embrace better approaches to the management of uncertainty inherent in climate policy decisions by (1) strengthening its focus on decision making under uncertainty and outright ambiguity, exploring options beyond the standard expected utility framework (e.g., Millner, Dietz, and Heal 2013; Heal and Millner 2014) and (2) estimating how the uncertainty itself affects its economic and financial cost estimates of climate damage and, ultimately, the optimal price for each ton of CO2 and other greenhouse gases released (e.g., Stern 2016). Evidence of Discrepancies Between Scientific and Economic Assessments of Climate Impacts IAMs typically combine a deterministic economic growth model with a simplified model of the carbon cycle (National Academies of Sciences, Engineering, and Medicine 2017). The links between the physical and the economic building blocks go both ways: (1) economic output generates emissions that feed into the carbon cycle and (2) the climate model generates temperature changes that affect the economic outcome via an economic damage function. Although there is a large amount of literature documenting the many problems with the use of IAMs to estimate the costs of future climate change impacts (e.g., Stern 2016), we empathize with the architects of these IAMs. Estimating economic damage is a daunting task that requires an array of normative judgments. The authors of some IAMs are forthcoming about their models’ limitations. Nordhaus (1992), for example, concludes his first article about the Dynamic Integrated Climate–Economy (DICE) model by pointing to “a number of important qualifications,” among them uncertainty and risk aversion. Meanwhile, many of the significant recent climate econometric advances (e.g., Burke, Hsiang, and Miguel 2015; Hsiang et al. 2017) have yet to find their way into the IAMs used to calculate the optimal CO2 price or SC-CO2 (National Academies of Sciences, Engineering, and Medicine 2017). Moreover, the discrepancy between physical impact studies and economic estimates diverge sharply with greater amounts of warming (Lenton and Ciscar 2013). DICE, for example, projects a loss of less than 10 percent of global economic output as a result of raising the global mean surface temperature by 6°C (Wagner and Weitzman 2015). These discrepancies between the physical and the economic impact estimates are large, and they matter. However, physical impacts are often not translated into monetary terms and they have largely been ignored by climate economists (Hanemann 2016).3 Recommendations for the IPCC AR6 We urge the authors of AR6 to explore—and help guide the policy community toward—an explicit recognition of the risks, uncertainties, and ambiguities involved in the long climate–economic chain—from greenhouse gas emissions to concentrations, from concentrations to global average temperatures, from temperatures to climate damages, and from damages to how society can be expected to react. At the same time, AR6 could and should seek to advance the science and practice of IAMs themselves, in particular, how these models incorporate risks and uncertainties into calculations of the optimal CO2 price. More specifically, we recommend that the IPCC: 1. Strengthen its focus on decision making under uncertainty and outright ambiguity The simplicity of the expected utility framework, which weighs expected outcomes by the probability of occurrence, fails to capture a crucial characteristic of the climate policy decision problem; that is, it does not allow decision makers to express their subjective confidence in different sources of information contained in the model (Millner and Heal 2017). However, important probabilities in climate science are subjective or missing, which means information is lost if an expected utility model is used. Thus we recommend that AR6 examine how this loss of subjective confidence in different data affects optimal climate policy. Alternative frameworks for examining decision making under ambiguity exist. Instead of the technical expert calculus that is currently used, decisions concerning optimal climate policy should ideally move to public debates about the ethical choices that underlie different decision frameworks (Baldwin 2016). Thus taking uncertainty seriously implies that AR6 needs to include a debate about the correct model of rational decision making for climate policy, a recommendation supported by Brock and Hansen (2017), among others.4Arrow et al. (1996) could serve as a template for how such a debate might play out in the IPCC context. 2. Focus on estimating how the uncertainty itself affects economic and financial cost estimates of climate damage A second problem with the expected utility framework is that it does not consider ambiguity aversion, a widely held preference to avoid uncertainty (Ellsberg 1961). How can the effect of uncertainty on estimates of climate damage estimates be computed within the expected utility framework? As a starting point for answering this question, Weitzman (2012) proposes a steeper damage function that relies on input from an expert panel that explicitly considered physical tipping points. This damage function leads to a loss of global output of around 50 percent for a temperature increase of 6°C. In contrast, to this day, DICE continues to rely on a 1994 expert survey that focused on the likelihood of a 25 percent “Great Depression”-size loss (Nordhaus and Sztorc 2013). Wouter Botzen and van den Bergh (2012) show that when physical tipping points are incorporated into DICE, the optimal carbon price rises to $350 by the end of the 21st century. Finally, Millner, Dietz, and Heal (2013) find that incorporating ambiguity aversion directly into the DICE model leads to more stringent optimal abatement. Thus climate policy recommendations based on the current framework seriously underestimate the economic value of climate damages. Another strategy for addressing uncertainty is to add probabilistic tipping points to the climate sector in an IAM. Lemoine and Traeger (2016) study the effect of ambiguous tipping points on the optimal carbon price and find that specific tipping points increase the optimal carbon price, but only by a small amount. In contrast, Lemoine (2017) finds that uncertainty concerning both climate science and economics increases the optimal CO2 price by 60 percent. In addition, in a study of the channels by which uncertainty affects the optimal carbon price, Lemoine and Rudik (2017) show that future economic adjustment costs are likely to be the dominant source of additional damage. Similarly, Daniel, Litterman, and Wagner (2016) find that when a climate–economy model is calibrated to reflect financial risk attitudes, the uncertainty in climate impacts increases the optimal CO2 price. Conclusions: Toward a Revamping of Climate Damage Estimates in AR6 Two distinct conclusions emerge from our review of the state of climate economics. First, the expected utility framework fails to capture important dimensions of the climate decision problem. Second, when uncertainty is explicitly considered within the expected utility framework, estimates of the economic damages from climate change generally increase, often by as much as an order of magnitude. Once again, this suggests that AR6 will be able to provide policymakers with a more robust and rigorous way of assessing the potential future risks of economic damage from climate change by (1) strengthening its focus on decision making under uncertainty and outright ambiguity and (2) estimating how the uncertainty itself affects its economic and financial cost estimates of climate damage. Our hope is that AR6 can act as a broad forum that brings together scientists and economists with a goal of quantifying the impacts of climate change. Such a forum should follow the modular approach to building IAMs proposed by the National Academies of Sciences, Engineering, and Medicine (2017). In this way, AR6 can carry out the daunting task of helping to revamp both existing climate damage estimates and their use for climate policy decision making and further its mission to “provide the world with a clear scientific view on the current state of knowledge in climate change and its potential environmental and socio-economic impacts” (Intergovernmental Panel on Climate Change 2018). Footnotes 1 The other four categories are threats to endangered species and unique systems, damages from extreme climate events, effects that fall most heavily on developing countries and the poor within countries, and large-scale high-impact events (Oppenheimer et al. 2014). 2 The “social cost of carbon”—or more accurately the SC-CO2—is the marginal damage caused by the emission of one ton of CO2 given present emissions trajectories. This is distinct from the optimal CO2 price, which depicts the price along an optimal trajectory. 3 For additional references, see the online supplementary materials. 4 Weitzman’s (2009, 2011) “Dismal Theorem” and argument concerning the climate sensitivity distribution’s “heavy” or outright “fat” tails potentially dwarfing expected-value arguments holds particular sway in this regard (Wagner and Weitzman 2015). References Arent D. J. , Tol R. S. J. , Faust E. , Hella J. P. , Kumar S. , Strzepek K. M. , Tóth F. L. , Yan D. . 2014 . Key economic sectors and services. In: Climate Change 2014: Impacts, Adaptation, and Vulnerability. Part A: Global and Sectoral Aspects. Contribution of Working Group II to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change , ed. Field C. B. , Barros V. R. , Dokken D. J. , Mach K. J. , Mastrandrea M. D. , Bilir T. E. , Chatterjee M. , Ebi K. L. , Estrada Y. O. , Genova R. C. , Girma B. , Kissel E. S. , Levy A. N. , MacCracken S. , Mastrandrea P. R. , White L. L. , 659 – 708 . New York : Cambridge University Press . Arrow K. J. , Cline W. R. , Maler K.-G. , Munasinghe M. , Squitieri R. , Stiglitz J. E. . 1996 . Intertemporal equity, discounting, and economic efficiency. In Climate Change 1995: Economic and Social Dimensions of Climate Change , ed. Bruce J. P. , Lee H. , Haites E. F. , 125 – 44 . Cambridge : Cambridge University Press . Baldwin E. 2016 . Choosing in the dark: incomplete preferences, and climate policy. Mimeo . Brock W. A. , Hansen L. P. . 2017 . Wrestling with uncertainty in climate economic models. Mimeo . Burke M. , Hsiang S. M. , Miguel E. . 2015 . Global non-linear effect of temperature on economic production . Nature 527 : 235 – 39 . Google Scholar CrossRef Search ADS PubMed Daniel K. D. , Litterman R. B. , Wagner G. . 2016 . Applying asset pricing theory to calibrate the price of climate risk. Working paper 22795, National Bureau of Economic Research, Cambridge, MA. Ellsberg D. 1961 . Risk, ambiguity, and the Savage axioms . Quarterly Journal of Economics 75 4 : 643 – 69 . Google Scholar CrossRef Search ADS Hanemann M. 2016 . Non-market damages from climate change. Presentation given at Meeting 5, Assessing Approaches to Updating the Social Cost of Carbon, National Academies of Sciences, Engineering and Medicine, May 5, 2016. http://sites.nationalacademies.org/cs/groups/dbassesite/documents/webpage/dbasse_172600.pdf Heal G. , Millner A. . 2014 . Uncertainty and decision making in climate change economics . Review of Environmental Economics and Policy 8 1 : 120 – 37 . Google Scholar CrossRef Search ADS Hsiang S. , Kopp R. , Jina A. , Rising J. , Delgado M. , Mohan S. , Rasmussen D. J. , Muir-Wood R. , Wilson P. , Oppenheimer M. , Larsen K. , Houser T. . 2017 . Estimating economic damage from climate change in the United States . Science 356 : 1362 – 69 . Google Scholar CrossRef Search ADS PubMed Intergovernmental Panel on Climate Change . 2018 . Organization . https://www.ipcc.ch/organization/organization.shtml. Kopp R. E. , Shwom R. , Wagner G. , Yuan J. . 2016 . Tipping elements and climate-economic shocks: pathways toward integrated assessment . Earth’s Future 4 : 346 – 72 . Google Scholar CrossRef Search ADS Lemoine D. 2017 . The climate risk premium: how uncertainty affects the social cost of carbon. Working paper 15-01, Department of Economics, University of Arizona. Lemoine D. , Rudik I. . 2017 . Managing climate change under uncertainty: recursive integrated assessment at an inflection point . Annual Review of Resource Economics 9 : 117 – 42 . Google Scholar CrossRef Search ADS Lemoine D. , Traeger C. P. . 2016 . Ambiguous tipping points . Journal of Economic Behavior & Organization 132 : 5 – 18 . Google Scholar CrossRef Search ADS Lenton T. M. 2013 . Environmental tipping points . Annual Review of Environment and Resources 38 : 1 – 29 . Google Scholar CrossRef Search ADS Lenton T. M. , Ciscar J.-C. . 2013 . Integrating tipping points into climate impact assessments . Climatic Change 117 3 : 585 – 97 . Google Scholar CrossRef Search ADS Millner A. , Dietz S. , Heal G. . 2013 . Scientific ambiguity and climate policy . Environmental and Resource Economics 55 1 : 21 – 46 . Google Scholar CrossRef Search ADS Millner A. , Heal G. . 2017 . Uncertainty and ambiguity in environmental economics: conceptual issues. Forthcoming in Handbook of Environmental Economics . National Academies of Sciences, Engineering, and Medicine . 2017 . Valuing Climate Damages: Updating Estimation of the Social Cost of Carbon Dioxide. Washington, DC : National Academies Press . Nordhaus W. D. 1992 . An optimal transition path for controlling greenhouse gases . Science 258 : 1315 – 19 . Google Scholar CrossRef Search ADS PubMed Nordhaus W. D. , Sztorc P. . 2013 . DICE 2013R: Introduction and User's Manual , 2nd ed. dated October 31, 2013. Oppenheimer M. , Campos M. , Warren R. , Birkmann J. , Luber G. , O’Neill B. , Takahashi K. . 2014 . Emergent risks and key vulnerabilities. In: Climate Change 2014: Impacts, Adaptation, and Vulnerability. Part A: Global and Sectoral Aspects. Contribution of Working Group II to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change , ed. Field C. B. , Barros V. R. , Dokken D. J. , Mach K. J. , Mastrandrea M. D. , Bilir T. E. , Chatterjee M. , Ebi K. L. , Estrada Y. O. , Genova R. C. , Girma B. , Kissel E. S. , Levy A. N. , MacCracken S. , Mastrandrea P. R. , White L. L. , 1039 – 99 . New York : Cambridge University Press . Stern N. 2016 . Current climate models are grossly misleading . Nature 530 : 407 – 9 . Google Scholar CrossRef Search ADS PubMed Wagner G. , Weitzman M. L. . 2015 . Climate Shock: The Economic Consequences of a Hotter Planet. Princeton, NJ : Princeton University Press . Google Scholar CrossRef Search ADS Weitzman M. L. 2009 . On modeling and interpreting the economics of catastrophic climate change . Review of Economics and Statistics 91 1 : 1 – 19 . Google Scholar CrossRef Search ADS Weitzman M. L. 2011 . Fat-tailed uncertainty in the economics of catastrophic climate change . Review of Environmental Economics and Policy 5 2 : 275 – 92 . Google Scholar CrossRef Search ADS Weitzman M. L. 2012 . GHG targets as insurance against catastrophic climate damages . Journal of Public Economic Theory 14 2 : 221 – 44 . Google Scholar CrossRef Search ADS World Bank Group . 2014 . Turn Down the Heat: Confronting the New Climate Normal . Washington, DC : World Bank . Wouter Botzen W. J. , van den Bergh J. C. J. M. . 2012 . How sensitive is Nordhaus to Weitzman? Climate policy in DICE with an alternative damage function . Economics Letters 117 1 : 372 – 74 . Google Scholar CrossRef Search ADS © The Author(s) 2018. Published by Oxford University Press on behalf of the Association of Environmental and Resource Economists. This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0/), which permits non-commercial re-use, distribution, and reproduction in any medium, provided the original work is properly cited. For commercial re-use, please contact firstname.lastname@example.org
Review of Environmental Economics and Policy – Oxford University Press
Published: Jul 1, 2018
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