Abstract
The need for regulation of greenhouse gases (GHGs) sets policy challenges to the energy industries in the twenty-first century, given the major climate threat that has manifested in recent decades. The focus will thus be on environment-related issues, including emissions, renewable-based technology, and change in consumer-use patterns. In this context, policy aims at preserving and maintaining security of supply as well as a competitive environment within both power generation and energy-intensive industries. There are enormous uncertainties regarding the effect of GHGs on climate change in Latin America and on the structure of the electricity sector in the future. In spite of the obvious threats, these conditions also provide opportunities not yet explored. A low-carbon policy aims at changes regarding: regulation, demand, supply, market structure, management, and in general, the competitiveness of the power generation industry. In this direction, it is neither clear what structural changes should be adopted within the electricity sector, nor what are the opportunities that this policy may offer. This article assesses the effect of GHG policy on the Colombian electricity sector, based on system dynamics simulation; it also indicates how emission costs and incentives in the electricity sector induce technology changes leading towards a low carbon economy.
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Bartz, S., Kelly, D.L.: Economic growth and the environment: theory and facts. Resour. Energy Econ. 30, 115–149 (2007)
Bunn, D., Larsen, E.: Assessment of the uncertainty in future UK electricity investment using an industry simulation model. Util. Policy. 4, 229–236 (1994)
CEC (Commission of the European Communities: Directive 2009/29/EC of the European Parliament and of the Council of 23 April 2009 amending Directive 2003/87/EC so as to improve and extend the greenhouse gas emission allowance trading scheme of the Community (Text with EEA relevance), OJ L 140, 5.6.2009, pp. 63–87. Brussels (2009)
Collantes, G.O.: Incorporating stakeholders’ perspectives into models of new technology diffusion: the case of fuel-cell vehicles. Technol. Forecast. Soc. Chang. 74, 267–280 (2007). doi:10.1016/j.techfore.2006.02.001
Comisión de Regulación de Energía y Gas.: Resolución No 24 de 1995. Por la cual se reglamentan los aspectos comerciales del mercado mayorista de energía en el sistema interconectado nacional, que hacen parte del Reglamento de Operación. Colombia. http://www.creg.gov.co/html/i_portals (1995). Accessed 18 Oct 2011
Dyner, I., Franco, C.J.: Consumers’ bounded rationality: the case of competitive energy markets. Syst. Res. Behav. Sci. 389, 373–389 (2004)
Dyner, I., Smith, R.A.R., Peña, G.E.: System dynamics modelling for residential energy efficiency analysis and management. J. Oper. Res. Soc. 46, 1163–1173 (1995)
Dyner, I., Cardenas, L., Franco, C.J.: A system dynamics model for assessing the UK carbon market. 29th International Conference of the System Dynamics Society. p. 15 (2011)
Dyner, I., Franco, C., Cárdenas, L.: Making progress towards defossilisation: modelling low-carbon policy for power generation. 30th International Conference of the System Dynamics Society, p. 11. St. Gallen, Switzerland (2012)
Dyner, I., Franco, C.J., Cárdenas, L.: Assessing policy for mitigating greenhouse gases in electricity. The 31st International Conference of the System Dynamics Society, p. 20. Cambridge (2013)
Fiddaman TS: Feedback Complexity in integrated climate-economy models. Ph.D. Thesis, MIT Sloan School of Management, Cambridge (1997)
Ford, A.: Estimating the impact of efficiency standards on the uncertainty of the northwest electric system. Oper. Res. 38, 580–597 (1990)
Ford, A.: Simulation scenarios for rapid reduction in carbon dioxide emissions in the western electricity system. Energy Policy. 36, 443–455 (2008). doi:10.1016/j.enpol.2007.09.023
Ford, A.: Greening the economy with new markets : System Dynamics Simulations of Energy and Environmental Markets. In: System Dynamics Society (ed.) The 28th international conference of the System Dynamics Society, pp. 1–26. Seoul, Korea (2010)
Kossoy A, Ambrosi P: State and trends of the carbon market 2010, p. 89. World Bank, Washington DC (2010)
Negro, S., Hekkert, M., Alkemade, F.: Seven Typical system failures that hamper the diffusion of sustainable energy technologies. ERSCP-EMSU Conference, pp. 1–21. Delft, Netherlands (2010)
Newbery D: Privatization, restructuring, and regulation of network utilities. MIT Press, Cambridge (1999)
North, D.: Institutions, institutional change, and economic performance. Cambridge Universitiy Press (1990)
Olsen, K.H.: The clean development mechanism’s contribution to sustainable development: a review of the literature. Clim. Chang. 84, 59–73 (2007). doi:10.1007/s10584-007-9267-y
Qudrat-Ullah, H., Davidsen, P.I.: Understanding the dynamics of electricity supply, resources and pollution. Pak. Case Energy. 26, 595–606 (2001). doi:10.1016/S0360-5442(01)00019-6
Rao, K.U., Kishore, V.V.N.: A review of technology diffusion models with special reference to renewable energy technologies. Renew. Sustain. Energy Rev. 14, 1070–1078 (2010). doi:10.1016/j.rser.2009.11.007
Schwarz, N., Ernst, A.: Agent-based modeling of the diffusion of environmental innovations—An empirical approach. Technol. Forecast. Soc. Chang. 76, 497–511 (2009). doi:10.1016/j.techfore.2008.03.024
Sterman, J.D., Sweeney, L.B.: Cloudy skies: assessing public understanding of global warming. Sist. Dyn. Rev. 18, 207–240 (2002)
Sterman, J., Fiddaman, T., Franck, T., et al.: Climate interactive : the C-ROADS climate policy model. Syst. Dyn. Rev. 28, 295–305 (2012). doi:10.1002/sdr
Stern N: The economics of climate change: the stern rReview, p. 712. Cambridge University Press, Cambridge (2007)
UNFCCC: Para comprender el cambio climático: guía elemental de la convención marco de la Naciones Unidas y el Protocolo de Kyoto, p. 21. Bonn. http://unfccc.int/resource/docs/publications/beginner_sp.pdf (2002) Accessed 7 June 2010
UNFCCC: Cuidar el clima, Guía de la Convención Marco sobre el Cambio Climático y el Protocolo de Kyoto. 50 (2005). doi:92-9219-022-9
UPME: Plan de Expansión de Referencia Generación—Transmisión 2012–2025. Unidad de Planeación Minero Energética—UPME. Bogotá, Colombia. http://www.upme.gov.co/Docs/Plan_Expansion/2012/PLAN_COMPLETO_2012–2025.pdf(2012). Accessed 5 March 2013
XM: Descripción del sistema eléctrico colombiano. In: Información operativa y comercial. http://www.xm.com.co/Pages/DescripciondelSistemaElectricoColombiano.aspx (2012). Accessed 1 Oct 2012
Zachmann G, Von Hirschhausen C: First evidence of asymmetric cost pass-through of EU emissions allowances: examining wholesale electricity prices in Germany. Econ. Lett. 99(3), 465–469 (2008)
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Dyner, I., Franco, C., Cardenas, L. (2013). Making Progress Towards Emissions Mitigation: Modeling Low-Carbon Power Generation Policy. In: Qudrat-Ullah, H. (eds) Energy Policy Modeling in the 21st Century. Understanding Complex Systems. Springer, New York, NY. https://doi.org/10.1007/978-1-4614-8606-0_12
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