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Evaluation of CO2 Reduction Effected by GHG Reduction Policy of Vehicle
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 Title & Authors
Evaluation of CO2 Reduction Effected by GHG Reduction Policy of Vehicle
Park, Yeon Jae; Kwon, Sang Il; Lee, Jae Young;
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Greenhouse gas (GHG) emissions have given rise to climate change which is one of the most serious environmental challenges that the world faces today. In response, Republic of Korea has proposed "Low Carbon, Green Growth" as a new economic paradigm accompanying with the ultimate aim of building a sense of responsibility for the environment. Korean government has set the ambitious national GHG emission reduction target which aims 37% reduction in the business-as-usual (BAU) level of 2030. The transportation sector plays a key role in this target. In the transportation sector, the GHG reduction target of 34.3% in the BAU level by 2020 has been allocated in order to consider the industrial specificity. Furthermore, it is known that the GHG reduction in the transportation sector has relatively minimal side effects compared to those of other sectors. In order to meet this national GHG reduction target, Korean government has set emission regulation of vehicle for 2020. The purpose of this study is to evaluate the reduction effects by the average GHG regulation of vehicles. emissions, between 2009 and 2013 were analysed by reduction measure such as technology improvement, light-weight, segment shift, diesel vehicle sales. During this period, of vehicle was reduced every year by 19.9 g/km (i.e., 3.3% reduction per year). reduction of imported vehicle is greater than domestic vehicle because of segment shift toward small size vehicle and higher diesel vehicle sales.
;BAU;Greenhouse gas;Segment shift;Emission target;
 Cited by
Drake, D., T. Walton, M. Whinihan, and D. Aldorfer (2012) Using Economic Analysis to Assess the Viability of Post-2016 MY Greenhouse Gas Emission and Fuel Economy Standards for Light Duty Vehicles, Journal of Society of Automotive Engineers, 2012-01-0754. (Internet printed) crossref(new window)

European Commission (EC) (2009) Setting Emission Performance Standards for New Passenger Cars as Part of the Community's Integrated Approach to Reduce $CO_2$ Emissions form Light-Duty Vehicles (EC No 443/2009).

European Environment Agency (EEA) (2014) $CO_2$ Emissions Performance of Car Manufacturers in 2012.

Francois, C. (2009) $CO_2$ Emissions from New Cars And Vehicle Weight in Europe; How the EU Regulation Could Have Been Avoided and How to Reach It?, Energy Policy, 37(10), 3832-3842. crossref(new window)

Fulton, L., P. Cazzola, and F. Cuenot (2009) IEA Mobility Mode (MOMo) And Its Use in the ETP 2008, Energy Policy, 37(10), 3758-3768. crossref(new window)

Greenhouse Gas Inventory & Research Center (GIR) (2014) National Greenhouse Gas Inventory Report of Korea.

International Council on Clean Transportation (IPCC) (2012) Global Comparison of Light-Duty Vehicle Fuel Economy/GHG Emissions Standards.

Kim, Y.T., H.K. Lee, J.H. Kang, S.B. Han, and Y.J. Chung (2008) Relationship between $CO_2$ Emission and Fuel Consumption Rate according to Used Fuels at Driving Mode, Journal of Energy Engineering, 17 (4), 227-232. (in Korean with English abstract)

Lee, J.K., G.J. Yong, J.H. Lee, K.B. Lee, Y.S. Hong, H.W. Lee, H. Jung, and J.S. Lim (2005) The Study on the Fuel Economy according to the Variable Weight of Passenger Car, Journal of Korean Society of Automotive Engineers, KSAE052-F0293, 1861-1866. (in Korean with English abstract)

Lumberas, J., M. Valdes, R. Borge, and M.E. Rodriguez (2008) Assessment of Vehicle Emissions Projections in Madrid (Spain) from 2004 to 2012 Considering Several Control Strategies, Transportation Research Part A: Policy and Practice, 42(4), 646-658. crossref(new window)

Ministry of Environment (MOE) (2014) Notice of the Standards for the Efficiency of Average Energy Consumption of Automobiles, Standards for Allowable Emission of Greenhouse Gases form Automobiles And the Application and Management.

Ministry of Environment (MOE) (2014) Roadmap for National Greenhouse Gas Reduction Goal.

Pasaoglu, G., M. Honselaar, and C. Thiel (2012) Potential Vehicle Fleet $CO_2$ Reductions and Cost Implications for Various Vehicle Technology Deployment Scenarios in Europe, The International Journal of the Political, Economic, Planning, Environmental and Social Aspect of Energy, 40(1), 404-421.

Propfe, B., D. Kreyenberg, J. Wind, and S. Schmid (2013) Market Penetration Analysis of Electric Vehicles in the German Passenger Car Market Towards 2030, International Journal of Hydrogen Energy, 38(13), 5201-5208. crossref(new window)

Silva, C., M. Ross, and T. Farias (2009) Analysis and Simulation of "Low-Cost" Strategies to Reduce Fuel Consumption and Emissions in Conventional Gasoline Light-Duty Vehicles, Energy Conversion and Management, 50(2), 215-222. crossref(new window)

Stocker, T.F., D. Qin, G.-K. Plattner, M. Tignor, S.K. Allen, J. Boschung, A. Nauels, Y. Xia, V. Bex, and P.M. Midgley (2013) Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the intergovernmental Panel on Cilmate Change.

United Nations Framework Convention on Climate Change (UNFCCC) (2015) Adoption of the Paris Agreement.

Yan, X. (2009) Energy Demand And Greenhouse Gas Emissions During the Production of a Passenger Car in China, Energy Conversion and Management, 50(12), 2964-2966. crossref(new window)