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Energy Efficiency

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01-06-2015 | Original Article

Urban energy consumption and CO₂ emissions in Beijing: current and future

Authors: Hao Yu, Su-Yan Pan, Bao-Jun Tang, Zhi-Fu Mi, Yan Zhang, Yi-Ming Wei

Published in: Energy Efficiency | Issue 3/2015

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Abstract

This paper calculates the energy consumption and CO₂ emissions of Beijing over 2005–2011 in light of the Beijing’s energy balance table and the carbon emission coefficients of IPCC. Furthermore, based on a series of energy conservation planning program issued in Beijing, the Long-range Energy Alternatives Planning System (LEAP)-BJ model is developed to study the energy consumption and CO₂ emissions of Beijing’s six end-use sectors and the energy conversion sector over 2012–2030 under the BAU scenario and POL scenario. Some results are found in this research: (1) During 2005–2011, the energy consumption kept increasing, while the total CO₂ emissions fluctuated obviously in 2008 and 2011. The energy structure and the industrial structure have been optimized to a certain extent. (2) If the policies are completely implemented, the POL scenario is projected to save 21.36 and 35.37 % of the total energy consumption and CO₂ emissions than the BAU scenario during 2012 and 2030. (3) The POL scenario presents a more optimized energy structure compared with the BAU scenario, with the decrease of coal consumption and the increase of natural gas consumption. (4) The commerce and service sector and the energy conversion sector will become the largest contributor to energy consumption and CO₂ emissions, respectively. The transport sector and the industrial sector are the two most potential sectors in energy savings and carbon reduction. In terms of subscenarios, the energy conservation in transport (TEC) is the most effective one. (5) The macroparameters, such as the GDP growth rate and the industrial structure, have great influence on the urban energy consumption and carbon emissions.

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Title: Urban energy consumption and CO2 emissions in Beijing: current and future
Authors: Hao Yu
Su-Yan Pan
Bao-Jun Tang
Zhi-Fu Mi
Yan Zhang
Yi-Ming Wei
Publication date: 01-06-2015
Publisher: Springer Netherlands
Published in: Energy Efficiency / Issue 3/2015
Print ISSN: 1570-646X
Electronic ISSN: 1570-6478
DOI: https://doi.org/10.1007/s12053-014-9305-3

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