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Global Climate Control: Is There a Better Strategy Than Reducing Greenhouse Gas Emissions?

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  • Carlin, Alan

Abstract

Many environmentalists and some developed nations appear to have concluded that there is one Many environmentalists and some developed nations appear to have concluded that there is one climate change problem, global warming, and that there is only one solution to it, reducing greenhouse gas emissions, usually through the Kyoto Protocol. This paper argues instead that there are actually four major inter-related problems and concludes that several different approaches, including engineered climate selection, would be required to solve all of them. Although some measures can address certain climate change problems, none can address all of them. The paper first reviews the four major climate change problems, analyses whether the most prominent of the greenhouse gas control approaches (the Kyoto Protocol) is likely to be either effective or efficient in solving them, and then analyses both management and technological alternatives to this approach. The paper concludes that the most efficient and effective approach would be to actively pursue both engineered climate selection approaches involving radiative forcing using stratospheric particles optimized for this purpose as well as a new effort to reduce ocean acidification, with immediate priority given to the former in order to solve all the non-ocean acidification problems quickly while the more difficult, much slower, and much more costly effort to reduce ocean acidification is analyzed and carried out. This two-fold approach could be used to rapidly reduce the risks from adverse feedback/tipping point problems from global warming and from global cooling from major volcanic eruptions, and to rapidly stabilize average global temperatures at any desired level. This should also allow a little time for a new effort to better understand ocean acidification and design and carry out a careful program to reduce it directly, or possibly to decrease the carbon dioxide levels themselves to the extent that this is the most effective and lowest cost approach. If the latter, this should result in the lowest possible costs of carbon dioxide control by stretching out the period in which they would be made given the sensitivity of the costs of carbon dioxide emissions reductions to the rapidity with which they occur.

Suggested Citation

  • Carlin, Alan, 2006. "Global Climate Control: Is There a Better Strategy Than Reducing Greenhouse Gas Emissions?," National Center for Environmental Economics-NCEE Working Papers 280850, United States Environmental Protection Agency (EPA).
  • Handle: RePEc:ags:nceewp:280850
    DOI: 10.22004/ag.econ.280850
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    References listed on IDEAS

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    1. Mark Lasky, 2003. "The Economic Costs of Reducing Emissions of Greenhouse Gases: A Survey of Economic Models: Technical Paper 2003-03," Working Papers 14414, Congressional Budget Office.
    2. Nordhaus, William D., 1993. "Rolling the 'DICE': an optimal transition path for controlling greenhouse gases," Resource and Energy Economics, Elsevier, vol. 15(1), pages 27-50, March.
    3. Alan Manne & Richard Richels, 1992. "Buying Greenhouse Insurance: The Economic Costs of CO2 Emission Limits," MIT Press Books, The MIT Press, edition 1, volume 1, number 026213280x, December.
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