China's regional CO2 emissions reduction potential: A study of Chongqing city

Applied Energy

Volumn 162, Issue , 2016, Pages 1345-1354

  Tan, Xianchun ^a   Dong, Lele ^a   Chen, Dexue ^b   Gu, Baihe ^a   Zeng, Yuan ^a  

^a Chinese Academy of Sciences   (China)

^b UNIVERSITY OF CHINESE ACADEMY OF SCIENCES   (China)

Author keywords

CO2 emissions; LMDI; Low carbon development; Scenario analysis; STIRPAT model

Indexed keywords

EMISSION CONTROL; ENERGY EFFICIENCY; GAS EMISSIONS;

CARBON INTENSITY REDUCTIONS; EMISSION REDUCTION POTENTIALS; EMISSION REDUCTION TARGETS; LMDI; LOW-CARBON DEVELOPMENT; LOW-CARBON TRANSITIONS; SCENARIO ANALYSIS; STIRPAT MODELS;

GREENHOUSE GASES;

CARBON DIOXIDE; CARBON EMISSION; EMISSION CONTROL; ENERGY EFFICIENCY; ESTIMATION METHOD; GREENHOUSE GAS; INDUSTRIAL STRUCTURE; NUMERICAL MODEL; OPERATIONS TECHNOLOGY;

CHINA; CHONGQING;

EID: 84937112776     PISSN: 03062619     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.apenergy.2015.06.071     Document Type: Article

References (41)

1. Stern N. The economics of climate change: the stern review 2006, Cambridge University Press, Cambridge (UK).
2. IPCC. IPCC guidelines for national greenhouse gas inventories. See also: < 2006. http://www.ipcc.ch/ipccreports/methodology-reports.htm.
3. BSI, Carbon Trust, Defra. PAS 2050: 2008 Specification for the Assessment of the Life Cycle Greenhouse Gas Emissions of Goods and Services, [EB/OL. 2008a. <]. http://shop.bsigroup.com/en/Browseby-Sector/Energy-Utilities/PAS-2050/.
4. BSI, Carbon Trust, Defra. Guide to PAS 2050: How to Assess the Carbon Footprint of Goods and Services, [EB/OL. 2008b. <]. http://shop.bsigroup.com/en/Browse-by-Sector/Energy-Utilities/PAS-2050/.
5. Chang C.C. A multivariate causality test of carbon dioxide emissions, energy consumption and economic growth in China. Appl Energy 2010, 87:3533-3537.
6. Wachsmann U., Wood R., Lenzen M., Schaeffer R. Structural decomposition of energy use in Brazil from 1970 to 1996. Appl Energy 2009, 86:578-587.
7. Ang B.W. Decomposition analysis for policymaking in energy: which is the preferred method?. Energy Policy 2004, 32:1131-1139.
8. Ang B.W. The LMDI approach to decomposition analysis a practical guide. Energy Policy 2005, 33(7):867-871.
9. Torvanger A. Manufacturing sector carbon dioxide emissions in nine OECD countries, 1973-87: a divisia index decomposition to changes in fuel mix, emission coefficients, industry structure, energy intensities and international structure. Energy Econom 1991, 13(3):168-186.
10. Grubler G. The transportation sector: growing demand and emissions. Pacific Asian J Energy 1993, 3(2):179-199.
11. 2 intensities of power sector in Asia: a divisia decomposition analysis. Energy Econom 1996, 18(4):283-293.
12. Ang B.W. Decomposition analysis for policymaking in energy: which is the preferred method?. Energy Policy 2004, 32(9):1131-1139.
13. Cahill C.J., Gallachóir B.P. Monitoring energy efficiency trends in European industry: which top-down method should be used?. Energy Policy 2010, 38:6910-6918.
14. Lei L., Zhong Y.Y., Yuan X.L. Decomposition model and empirical study of regional carbon emissions for China. Modern Econom Sci 2011, 33(5):59-65. in Chinese.
15. 2 emissions in China. Energy 2011, 36(10):5909-5915.
16. 2 emissions in Greece for 1990-2002: a decomposition analysis and comparison of results using the Arithmetic Mean Divisia Index and Logarithmic Mean Divisia Index techniques. Energy 2008, 33(3):492-499.
17. Ang B.W., Liu N. Energy decomposition analysis: IEA model versus other methods. Energy Policy 2007, 35(3):1426-1432.
18. Sheinbaum C., Ozawa L., Castillo D. Using logarithmic mean Divisia index to analyse changes in energy use and carbon dioxide emissions in Mexico's iron and steel industry. Energy Econom 2010, 32(6):1337-1344.
19. Tian Y.H., Zhu Q.H., Geng Y. An analysis of energy-related greenhouse gas emissions in the Chinese iron and steel industry. Energy Policy 2013, 56:352-361.
20. 2 emissions in China's cement industry: a perspective from LMDI decomposition analysis. Energy Policy 2012, 50:821-832.
21. 2 emissions from final fuel use: an empirical analysis. Energy Policy 2007, 35(11):5892-5900.
22. 2 emission from energy use in Chongqing. Frontiers Earth Sci 2011, 5(1):103-109.
23. 2 emissions in China. Energies 2013, 6(5):2319-2337.
24. Hubacek K., Feng K.H., Chen B. Changing lifestyles towards a low carbon economy: an IPAT analysis for China. Energies 2012, 5(1):22-31.
25. Chen L., Yang Z.F., Chen B. Scenario analysis and path selection of low-carbon transformation in China based on a modified IPAT model. PloSONE 2013, 8(10):e77699.
26. Zhu Y.C., Zhang S.J. Analysis of Beijing district economy carbon discharge promotion factor basing on STIRPAT model. Special Zone Economy 2012, 1:77-79. in Chinese.
27. 2 emissions, energy consumption and economic growth in China using an improved grey model. Energy 2012, 40(1):400-409.
28. Wei Y.M., Fan Y., Wang Y., Liu L.C., Liang Q.M., Wu G., et al. Suggestions and solutions to carbon emission in China. Adv Climate Change Res 2006, 2(1):15-20. in Chinese.
29. Lin B.Q., Wu Y., Zhang L. Electricity saving potential of the power generation industry in China. Energy 2012, 40(1):307-316.
30. Hannah E.D., Brian P.G. Future energy and emissions policy scenarios in Ireland for private car transport. Energy Policy 2012, 51:172-183.
31. 2 emission in Iranian cement industry under various production and export scenarios. Energy Policy 2013, 58:75-89.
32. 2 emission. Energy Policy 2012, 51:683-695.
33. Gu B.H., Tan X.C., Chi H., Wang Y.Y. A carbon dioxide reduction potential model for chemical industry. Chin J Manage Sci 2013, 21(5):141-148. in Chinese.
34. 2 emission accounting method and application in Chongqing. Procedia Environ Sci 2011, 5:167-172.
35. Wang S., Tan X.C. The path choice of low-carbon transition: analysis of a municipality. Reforms 2010, 11:80-85. in Chinese.
36. Ang B.W., Zhang F.Q., Choi K. Factorizing changes in energy and environmental indicators through decomposition. Energy 1998, 23(6):489-495.
37. York R., Rosa E.A., Dietz T. STIRPAT, IPAT and ImPACT: analytic tools for unpacking the driving forces of environmental impacts. Ecol Econom 2003, 46(3):351-365.
38. Liu S.F., Deng J.L. Suitable range of the GM (1.1) Model. Syst Eng - Theory Practice 2000, (5):121-124. in Chinese.
39. Zhao A.W., Li D. Grey forecast of China's carbon dioxide emissions. Math Practice Theory 2012, 42(4):61-68. in Chinese.
40. Liu S.F., Dang Y.G., Fang Z.G., Xie N.M. Grey theory and its application 2010, Science Press, Beijing, in Chinese.
41. Cui L.B., Fan Y., Zhu L., Bi Q.H. How will the emissions trading scheme save cost for achieving China's 2020 carbon intensity reduction target. Appl Energy 2014, 136:1043-1052.