Abstract
We have compiled historical greenhouse gas emissions and their uncertainties on country and sector level and assessed their contribution to cumulative emissions and to global average temperature increase in the past and for a the future emission scenario. We find that uncertainty in historical contribution estimates differs between countries due to different shares of greenhouse gases and time development of emissions. Although historical emissions in the distant past are very uncertain, their influence on countries’ or sectors’ contributions to temperature increase is relatively small in most cases, because these results are dominated by recent (high) emissions. For relative contributions to cumulative emissions and temperature rise, the uncertainty introduced by unknown historical emissions is larger than the uncertainty introduced by the use of different climate models. The choice of different parameters in the calculation of relative contributions is most relevant for countries that are different from the world average in greenhouse gas mix and timing of emissions. The choice of the indicator (cumulative GWP weighted emissions or temperature increase) is very important for a few countries (altering contributions up to a factor of 2) and could be considered small for most countries (in the order of 10%). The choice of the year, from which to start accounting for emissions (e.g. 1750 or 1990), is important for many countries, up to a factor of 2.2 and on average of around 1.3. Including or excluding land-use change and forestry or non-CO2 gases changes relative contributions dramatically for a third of the countries (by a factor of 5 to a factor of 90). Industrialised countries started to increase CO2 emissions from energy use much earlier. Developing countries’ emissions from land-use change and forestry as well as of CH4 and N2O were substantial before their emissions from energy use.
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References
Andronova N, Schlesinger ME (2004) Importance of sulfate aerosol in evaluating the relative contributions of regional emissions to the historical global temperature change. Mitig Adapt Strategies Glob Chang 9(4):383–390
Cubasch U, Meehl GA, Boer GJ, Stouffer RJ, Dix M, Noda A, Senior CA, Raper S, Yap KS (2001) Projections of future climate change. In: Houghton JT, Ding Y, Griggs DJ, Noguer M, van der Linden PJ, Dai X, Maskell K, Johnson CA (eds) Climate change 2001: the scientific basis. Cambridge University Press, Cambridge
de Campos CP (2007) Historical land use change CO2 emissions from land use change to agriculture and pasture and the climate change contributions by country—the proposal by Brazil to the climate convention. Unpublished Doctoral thesis, University of Rio de Janeiro, Rio de Janeiro
de Campos CP, Muylaert Rosa P (2005) Historical CO2 emission and concentrations due to land use change of croplands and pastures by country. Sci Total Environ 346(1–3):149–155
den Elzen MGJ, Schaeffer M (2002) Responsibility for past and future global warming: uncertainties in attributing anthropogenic climate change. Clim Change 54:29–73
den Elzen MGJ, Beusen AHW, Rotmans J (1997) An integrated modeling approach to global carbon and nitrogen cycles: balancing their budgets. Glob Biogeochem Cycles 11(2):191–215
den Elzen MGJ, Berk MM, Schaeffer M, Olivier OJ, Hendriks C, Metz B (1999) The Brazilian proposal and other options for international burden sharing: an evaluation of methodological and policy aspects using the FAIR model. No. RIVM-Report 728001011, Bilthoven, The Netherlands. Available at http://www.mnp.nl/en
den Elzen MGJ, Schaeffer M, Eickhout B (2002) Responsibility for past and future global warming: time horizon and non-linearities in the climate system. No. RIVM-Report 728001022, National Institute of Public Health and the Environment, Bilthoven
den Elzen MGJ, Fuglestvedt JS, Höhne N, Trudinger CM, Lowe J, Matthews BJH, Romstadt B, de Campos CP, Andranova N (2005a) Analysing countries’ contribution to climate change: scientific uncertainties and methodological choices. Environ Sci Policy 8:614–636
den Elzen MGJ, Schaeffer M, Lucas P (2005b) Differentiating future commitments on the basis of countries’ relative historical responsibility for climate change: uncertainties in the ‘Brazilian proposal’ in the context of a policy implementation. Clim Change 71(3):277–301
Enting IG (1998) Attribution of greenhouse gas emissions, concentrations and radiative forcing. No. CSIRO Atmospheric Research Technical Paper No. 38. Aspendale Victoria, Australia
Filho MLG, Miguez M (1998) Time dependent relationship between emissions of greenhouse gases and climate change. Ministry of Science and Technology, Brazil
Friedlingstein P, Cox P, Betts R, Bopp L, Bloh WV, Brovkin V, Cadule P, Doney S, Eby M, Fung I, Bala G, John J, Jones C, Joos F, Kato T, Kawamiya M, Knorr W, Lindsay K, Matthews HD, Raddatz T, Rayner P, Reick C, Roeckner E, Schnitzler K-G, Schnur R, Strassmann K, Weaver AJ, Yoshikawa C, Zeng N (2006) Climate–carbon cycle feedback analysis: results from the C4MIP model intercomparison. J Clim 19:3337–3353
Fuglestvedt JS, Berntsen T, Godal O, Tora S (2001) Climate implications of GWP-based reductions in greenhouse gas emissions. Geophys Res Lett 27(3):409–412
Fuglestvedt JS, Shine KP, Berntsen T, Cook J, Lee DS, Stenke A, Skeie RB, Velders GJM, Waitz IA (2009) Transport impacts on atmosphere and climate: metrics. Atmos Environ. doi:10.1016/j.atmosenv.2009.04.044
Harvey D, Gregory J, Hoffert M, Jain A, Lal M, Leemans R, Raper S, Wigley T, Wolde JD (1997) An introduction to simple climate models used in the IPCC second assessment report. No. IPCC Technical Paper II. Intergovernmental Panel on Climate Change, Geneva, Switzerland
Höhne N (2002) Comparing indicators for contributions to climate change. No. contribution to phase II of the UNFCCC ‘assessment of contributions to climate change’. ECOFYS Energy & Environment, Cologne, Germany. Available at http://www.ecofys.com
Höhne N, Ullrich S (2003) Third expert meeting on scientific and methodological aspects of the proposal by Brazil, 8–9 September, Meeting Report. ECOFYS, Cologne. Available at http://www.match-info.net
Höhne N, Blok K (2005) Calculating historical contributions to climate change—discussing the ‘Brazilian proposal’. Clim Change 71(1):141–173
Houghton RA (2003) Emissions (and Sinks) of carbon from land-use change. (Estimates of national sources and sinks of carbon resulting from changes in land use, 1950 to 2000). Report to the world resources institute from the woods hole research center. Woods Hole Research Center, Woods Hole, MA, USA. Available at http://cait.wri.org
IEA (2006) CO2 Emissions from fuel combustion, 2006 edn. International Energy Agency
IMAGE Team (2001) The IMAGE 2.2 implementation of the SRES scenarios. A comprehensive analysis of emissions, climate change and impacts in the 21st century. CD-ROM Publication 481508018, Bilthoven, the Netherlands. Available at http://www.rivm.nl/image/
Ito A, Penner JE, Prather MJ, de Campos CP, Houghton RA, Kato T, Jain AK, Yang X, Hurtt GC, Frolking S, Fearon MG, Chini LP, Wang A, Price DT (2008) Can we reconcile differences in estimates of carbon fluxes from land-use change and forestry for the 1990s? Atmos Chem Phys 8:3291–3310
Joos F, Bruno M, Fink R, Siegenthaler U, Stocker TF, Quéré CL, Sarmiento JL (1996) An efficient and accurate representation of complex oceanic and biospheric models of anthropogenic carbon uptake. Tellus 48B:397–417
Joos F, Plattner G-K, Stocker TF, Marchal O, Schmittner A (1999) Global warming and marine carbon cycle feedbacks on future atmospheric CO2. Science 284:464–467
Klein Goldewijk CGM, Battjes JJ (1995) The IMAGE 2 hundred year (1890–1900) data base of the global environment (HYDE). RIVM Report, No. 481507008. National Institute of Public Health and the Environment (RIVM), Bilthoven, The Netherlands
Kurosawa A (2006) Multigas mitigation: an economic analysis using GRAPE model. The Energy Journal Multi-Greenhouse Gas Mitigation and Climate Policy (Special Issue #3)
Marland G, Boden TA, Andres RJ (2003) Global, regional, and national fossil fuel CO2 emissions. In: Carbon dioxide information analysis center ORNL, U.S. Department of Energy (ed) Trends: a compendium of data on global change. Oak Ridge, TN, USA. Available at http://cdiac.esd.ornl.gov/trends/emis/meth_reg.htm
Marland G, Boden TA, Andres RJ, Brenkert AL, Johnston CA (1999) Global, regional, and national fossil fuel CO2 emissions. In: Trends: a compendium of data on global change. Carbon Dioxide Information Analysis Center (CDIAC), Oak Ridge National Laboratory (ORNL), Oak Ridge, TN. Available at http://cdiac.esd.ornl.gov
Müller B, Höhne N, Ellermann C (2009) Differentiating (historic) responsibilities for climate change. Clim Pol 9(6):593–611
Muylaert de Araujo MS, de Campos CP, Rosa LP (2007) Historical emissions, by country, of N2O from animal manure management and of CH4 from enteric fermentation in domestic livestock. Clim Res 34(3):253–258
Pinguelli Rosa L, Ribeiro SK (1997) The share of responsibility between developed and developing countries in climate change. Greenhouse Gas Mitigation Paper presented at the international energy agency conference on GHG, Vancouver. Available at http://www.ivig.coppe.ufrj.br/doc/vancuver.pdf
Pinguelli Rosa L, Ribeiro SK (2001) The present, past, and future contributions to global warming of CO2 emissions from fuels. Clim Change 48:289–308
Prather MJ, Penner JE, Fuglestvedt JS, Kurosawa A, Lowe JA, Höhne N, Jain AK, Andronova N, Pinguelli L, Campos CPD, Raper SCB, Skeie RB, Stott PA, Aardenne JV, Wagner F (2009) Tracking uncertainties in the causal chain from human activities to climate. Geophys Res Lett 36:L05707. doi:05710.01029/02008GL036474
Ramaswamy V, Boucher O, Haigh J, Hauglusataine D, Haywood J, Myhre G, Nakajima T, Shi GY, Solomon S (2001) Atmospheric chemistry and greenhouse gases. In: Houghton JT, Ding Y, Groggs DJ, Nogour M, van der Linden PJ, Dai X, Maskell K, Johnson CA (eds) IPCC third assessment—climate change 2001, the scientific basis. Cambridge University Press, Cambridge
Raper SCB, Cubasch U (1996) Emulation of the results from a coupled general circulation model using a simple climate model. Geophys Res Lett 23(10):1107–1110
Raper SCB, Gregory JM, Osborn TJ (2001) Use of an upwelling-diffusion energy balance climate model to simulate and diagnose A/OGCM results. Clim Dyn 17(8):601–613
Rosa LP, Ribeiro SK, Muylaert MS, Campos CPD (2004) Comments on the Brazilian proposal and contributions to global temperature increase with different climate responses—CO2 emissions due to fossil fuels, CO2 emissions due to land use change. Energy Policy 32:1499–1510
Rotmans J, den Elzen MGJ (1992) Modelling feedback mechanisms in the carbon cycle. Tellus 42b:301–320
Schlesinger ME, Jiang K, Charlson RJ (1992) Implications of anthropogenic atmospheric sulphate for the sensitivity of the climate system. In: Climate change and energy policy. American Institute of Physics, New York
Shine KP, Fuglestvedt JS, Hailemariam K, Stuber N (2005) Alternatives to the global warming potential for comparing climate impacts of emissions of greenhouse gases. Clim Change 68(3):281–302
Siegenthaler U, Joos F (1992) Use of a simple model for studying oceanic tracer distributions and the global carbon cycle. Tellus 44B:186–207
Skeie RB, Fuglestvedt J, Berntsen T, Lund MT, Myhre G, Rypdal K (2009) Global temperature change from the transport sectors: historical development and future scenarios. Atmos Environ 43:6260–6270
Stott PA (2003) Attribution of regional-scale temperature changes to anthropogenic and natural causes. Geophys Res Lett 30(14):1728
Stott PA, Tett SFB, Jones GS, Allen MR, Mitchell JFB, Jenkins GJ (2000) External control of twentieth century temperature by natural and anthropogenic causes. Science 290(14):2133–2137
Trudinger CM, Enting IG (2005) Comparison of formalisms for attributing responsibility for climate change: non-linearities in the Brazilian Proposal. Clim Change 68(1–2):67–99
UNFCCC (1997) Paper no. 1: Brazil; proposed elements of a protocol to the united nations framework convention on climate change. No. UNFCCC/AGBM/1997/MISC.1/Add.3 GE.97. Bonn
UNFCCC (2002) Methodological issues, scientific and methodological assessment of contributions to climate change. Report of the expert meeting, Note by the secretariat. FCCC/SBSTA/2002/INF.14. Available at http://www.unfccc.int
UNFCCC UNFCoCCS (2005) 2005 Annex I party GHG inventory submissions (1990–2003). Common reporting format from Finland to the UNFCCC
USEPA (2006) Global anthropogenic non-CO2 greenhouse gas emissions: 1990–2020. Appendix A-D. United States Environmental Protection Agency, Washington, DC, USA. Available at http://www.epa.gov/nonco2/econ-inv/international.html
Van Vuuren DP, Lucas PL, Hilderink H (2007) Downscaling drivers of global environmental change scenarios: enabling use of the IPCC SRES scenarios at the national and grid level. Glob Environ Change 17:114–130
Wigley TML (1993) Balancing the carbon budget. Implications for projections of future carbon dioxide concentration changes. Tellus 45B(5):409–425
Wigley TML, Raper SCB (2001) Interpretation of high projections for global-mean warming. Science 293(5529):451–454
Wigley TML, Raper SCB (2002) Reasons for larger warming projections in the IPCC third assessment report. J Clim 15(20):2945–2952
Zwiers FW, Zhang XB (2003) Toward regional-scale climate change detection. Climate 16(5):793–797
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Höhne, N., Blum, H., Fuglestvedt, J. et al. Contributions of individual countries’ emissions to climate change and their uncertainty. Climatic Change 106, 359–391 (2011). https://doi.org/10.1007/s10584-010-9930-6
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DOI: https://doi.org/10.1007/s10584-010-9930-6