When technology and climate policy meet: Energy technology in an international policy context

Post-Kyoto International Climate Policy: Implementing Architectures for Agreement: Research from the Harvard Project on International Climate Agreements

Volumn , Issue , 2009, Pages 786-821

  Clarke, Leon ^a   Calvin, Kate ^a   Edmonds, Jae ^b   Kyle, Page ^a   Wise, Marshall ^b  

^a PACIFIC NORTHWEST NATIONAL LABORATORY   (United States)

^b UNIVERSITY OF MARYLAND   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

EID: 84926994615     PISSN: None     EISSN: None     Source Type: Book    
DOI: 10.1017/CBO9780511813207.026     Document Type: Chapter

References (36)

1. Baker, E., L. Clarke, and J. Weyant (2006). “R&D as a Hedge Against Climate Damages,” Climatic Change 78(1): 157–79.
2. Bosetti, V., C. Carraro, E. Massetti, and M. Tavoni (2007). “Optimal Energy Investment and R&D Strategies to Stabilize Atmospheric Greenhouse Gas Concentrations,” CEPR Discussion Paper 6549 and CESifo Working Paper N. 2133, FEEM Nota di Lavoro 95.07.
3. Bosetti, V., C. Carraro, and M. Tavoni (2008). “Delayed Participation of Developing Countries to Climate Agreements: Should Action in the EU and US be Postponed?” CEPR Working Paper 6967 and CESifo Working Paper N. 2445, FEEM Nota di Lavoro 70.08.
4. Brenkert, A., S. Smith, S. Kim, and H. Pitcher (2003). Model Documentation for the MiniCAM, PNNL 14337, Pacific Northwest National Laboratory, Richland, Washington.
5. Clarke, L., J. Edmonds, H. Jacoby, H. Pitcher, J. Reilly, and R. Richels (2007a). Scenarios of Greenhouse Gas Emissions and Atmospheric Concentrations, Sub-report 2.1A of Synthesis and Assessment Product 2.1 by the US Climate Change Science Program and the Subcommittee on Global Change Research, Department of Energy, Office of Biological & Environmental Research, Washington, DC.
6. Clarke, L., J. Edmonds, S. Kim, J. Lurz, H. Pitcher, S. Smith, and M. Wise (2007b). Documentation for the MiniCAM CCSP Scenarios, Battelle Pacific Northwest Division Technical Report, PNNL-16735.
7. Clarke, L., P. Kyle, M. Wise, K. Calvin, J. Edmonds, S. Kim, M. Placet, and S. Smith (2008b). CO2 Emissions Mitigation and Technological Advance: An Updated Analysis of Advanced Technology Scenarios, Technical Report PNNL-18075, Pacific Northwest National Laboratory.
8. Clarke, L. and J. Weyant (2002). “Modeling Induced Technological Change: An Overview,” in A. Grubler, N. Nakicenovic, and W. Nordhaus (eds.), Technological Change and the Environment. Washington, DC: Resources for the Future, pp. 320–63.
9. Clarke, L., J. Weyant, and A. Birky (2006). “On Sources of Technological Change: Assessing the Evidence,” Energy Economics 28: 579–95.
10. Clarke, L., J. Weyant, and J. Edmonds (2008a). “On Sources of Technological Change: What do the Models Assume?” Energy Economics 30: 409–24.
11. Clarke L., M. Wise, S. Kim, A. Thomson, R. Izaurralde, J. Lurz, M. Placet, and S. Smith (2006). Climate Change Mitigation: An Analysis of Advanced Technology Scenarios, Technical Report PNNL-16078, Pacific Northwest National Laboratory.
12. Crutzen, P. J., A. R. Mosier, K. A. Smith, and W. Winiwarter (2008). “N2O Release from Agro-Biofuel Production Negates Global Warming Reduction by Replacing Fossil Fuels,” Atmospheric Chemistry and Physics 8: 389–95.
13. Edmonds, J. and J. Reilly (1985). Global Energy: Assessing the Future, New York: Oxford University Press.
14. Edmonds, J., L. Clarke, J. Lurz, and M. Wise (2008). “Stabilizing CO2 Concentrations with Incomplete International Cooperation,” Climate Policy 8: 355–76.
15. Edmonds, J. A., M. A. Wise, J. J. Dooley, S. H. Kim, S. J. Smith, P. J. Runci, L. E. Clarke, E. L. Malone, and G. M. Stokes (2007). Global Energy Technology Strategy Addressing Climate Change: Phase 2 Findings from an International Public-Private Sponsored Research Program, College Park, MD: Joint Global Change Research Institute.
16. Goulder, L. and K. Mathai (2000). “Optimal CO2 Abatement in the Presence of Induced Technological Change,” Journal of Environmental Economics and Management 39(1): 1–38.
17. Goulder, L. and S. Schneider (1999). “Induced Technological Change and the Attractiveness of CO2 Abatement Policies,” Resource and Energy Economics 21: 211–53.
18. Grubb, M., J. Kohler, and D. Anderson (2002). “Induced Technological Change in Energy and Environmental Modeling,” Annual Review of Energy and the Environment 27: 271–308.
19. Grubb, M., T. Chapuis, and M. Ha-Duong (1995). “The Economics of Changing Course: Implications of Adaptability and Inertia for Optimal Climate Policy,” Energy Policy 23(4/5): 417–32.
20. GTSP (2000). Global Energy Technology Strategy: Addressing Climate Change, Global Technology Strategy Program.
21. Hoffert, M. I., K. Caldeira, G. Benford, D. R. Criswell, C. Green, H. Herzog, A. K. Jain, H. S. Kheshgi, K. S. Lackner, J. S. Lewis, H. D. Lightfoot, W. Manheimer, J. C. Mankins, M. E. Mauel, L. J. Perkins, M. E. Schlesinger, T. Volk, and T. M. L. Wigley (2002). “Advanced Technology Paths to Global Climate Stability: Energy for a Greenhouse Planet,” Science 298(1): 981–7.
22. IEA (2008). Energy Technology Perspectives 2008. Paris: IEA.
23. Keppo, I. and S. Rao (2006). “International Climate Regimes: Effects of Delayed Participation,” Technology Forecasting & Social Change 74: 962–79.
24. Kim S. H., J. A. Edmonds, J. Lurz, S. J. Smith, and M. A. Wise (2006). “The Objects: Framework for Integrated Assessment: Hybrid Modeling of Transportation,” The Energy Journal (Special Issue No. 2 2006): 63.
25. Loschel, A. (2002). “Technological Change in Economic Models of Environmental Policy: A Survey,” Ecological Economics 43: 105–26.
26. Manne, A. and R. Richels (2002). The Impact Of Learning-By-Doing on the Timing and Cost of CO2 Abatement, Working paper, AEI-Brookings Joint Center for Regulatory Studies.
27. Messner, S. (1997). “Endogenized Technological Learning in an Energy Systems Model,” Evolutionary Economics 7: 291–313.
28. Nordhaus, W. (2002). “Modeling Induced Innovation in Climate-Change Policy,” in A. Grubler, N. Nakicenovic, and W. Nordhaus (eds.), Technological Change and the Environment. Washington, DC: Resources for the Future, pp.182–209.
29. Pacala, S. and R. Socolow (2004). “Stabilization Wedges: Solving the Climate Problem for the Next 50 Years with Current Technologies,” Science 305: 968–72.
30. Popp, D. (2004). “Entice: Endogenous Technological Change in the DICE Model of Global Warming,” Journal of Environmental Economics and Management 48: 742–68.
31. Richels, R., T. Rutherford, G. Blanford, and L. Clarke (2007). “Managing the Transition to Climate Stabilization,” Climate Policy 7: 409–28.
32. Searchinger, Timothy, Ralph Heimlich, R. A. Houghton, Fengxia Dong, Amani Elobeid, Jacinto Fabiosa, Simla Tokgoz, Dermot Hayes, and Tun-Hsiang Yu (2008). “Use of U.S. Croplands for Biofuels Increases Greenhouse Gases Through Emissions from Land-Use Change,” Science 319: 1238–40.
33. United Nations (1992). Framework Convention on Climate Change. New York: United Nations.
34. Van Vuuren, D. P., M. G. J. den Elzen, P. L. Lucas, B. Eickhout, B. J. Strengers, B. van Ruijven, S. Wonink, and R. van Houdt (2007). “Stabilizing Greenhouse Gas Concentrations at Low Levels: An Assessment of Reduction Strategies and Costs,” Climatic Change 81: 119–59.
35. Wigley, T. M. L., R. Richels, and J. A. Edmonds (1996). “Economic and Environmental Choices in the Stabilization of Atmospheric CO2 Concentrations,” Nature 379(6562): 240–3.
36. Wrse, M., K. Calvin, A. Thomson, L. Clarke, B. Bond-Lamberty, R. Sands, S. J. Smith, A. Janetos, J. Edmonds (2009). “Implications of Limiting CO2 Concentrations for Land Use and Energy,” Science 324: 1183–6.