我国主要工业省区大气污染排放效率的地区差异、变化趋势与成因分解

Abstract
Figure/Table
References (31)
Related Citation (5)

Download: PDF (721 KB) HTML (1 KB)
Export: BibTeX | EndNote (RIS)

Abstract

Using the methods of the non-radial directional distance function (NRDDF) and the improved Luenberger productivity indicator with difference-based structure, this paper studied the regional differences, changing trends and causes decompositions of the atmospheric pollution emissions efficiency (APEE) of China's 13major industrial provinces from 2003 to 2012. The empirical results showed that: (1) the APEE of China's major industrial provinces was generally lower, and regional difference was obvious, at the same time the atmospheric pollution has the great potential for emissions reduction; (2) a key constraint on the APEE of China's major industrial provinces was the pure technical efficiency; (3) taken the whole or a certain pollutant, the increase of APEE presented the mode of the single wheel drived by the environmental technical progress completely, while the change of pure technical efficiency (PTE) and scale efficiency (SE) played the negative effects on that; (4) the APEE of China's major industrial provinces appeared Matthew effect, and the efficiency differences of the APEE among these provinces would probably continue to expand through the analysis of the advantages and disadvantages of provincial atmospheric pollution reduction.

Key words： atmospheric pollution emissions efficiency (APEE) industrial province regional differences changing trends causes decomposition

Received: 25 July 2016

PACS:	X51
	F061.5

	Service

	E-mail this article
	Add to my bookshelf
	Add to citation manager
	E-mail Alert
	RSS
	Articles by authors
	WANG Ke-liang
	MENG Xiang-rui
	YANG Li
	YANG Bao-chen
	WANG Jian-min
	CHENG Yun-he

Cite this article:

WANG Ke-liang,MENG Xiang-rui,YANG Li等. The regional differences, changing trends and causes decomposition of atmospheric pollution emissions efficiency of China's major industrial provinces[J]. CHINA ENVIRONMENTAL SCIENCECE, 2017, 37(3): 888-898.

URL:

http://manu36.magtech.com.cn/Jweb_zghjkx/EN/ OR http://manu36.magtech.com.cn/Jweb_zghjkx/EN/Y2017/V37/I3/888

[1]	Hu J L, Wang S C. Total-factor energy efficiency of regions in China [J]. Energy Policy, 2006,34(17):3206-3217.
[2]	魏楚,沈满洪.能源效率与能源生产率:基于DEA方法的省际数据比较 [J]. 数量经济技术经济研究, 2007,(9):110-121.
[3]	师博,沈坤荣.市场分割下的中国全要素能源效率:基于超效率DEA方法的经验分析 [J]. 世界经济, 2008,(9):49-59.
[4]	李世祥,成金华.中国主要工业省区能源效率分析:1990~2006年 [J]. 数量经济技术经济研究, 2008,(10):32-43.
[5]	吴琦,武春友.基于DEA的能源效率评价模型研究 [J]. 管理科学, 2009,22(1):103-112.
[6]	袁晓玲,张宝山,杨万平.基于环境污染的中国全要素能源效率研究 [J]. 中国工业经济, 2009,(2):76-86.
[7]	汪克亮,杨宝臣,杨力.考虑环境效应的中国省际全要素能源效率研究 [J]. 管理科学, 2010,23(6):100-111.
[8]	Zhou P, Ang B W, Han J Y. Total-factor carbon emission performance: a Malmquist index analysis [J]. Energy Economics, 2010,32(1):194-201.
[9]	王奇,李明全.基于DEA方法的我国大气污染治理效率评价 [J]. 中国环境科学, 2012,32(5):942-946.
[10]	Chung Y, Fare R, Grosskopf S. Productivity and undesirable output: a directional distance function approach [J]. Journal of Environmental Management, 1997,51(3):229-240.
[11]	Macpherson A J, Principe P P, Smith E R A. DDF approach to regional environmental-economic assessments [J]. Ecological Economics, 2010,69:1918-1925.
[12]	Riccardi R, Oggioni G., Toninelli R.Efficiency analysis of world cement industry in presence of undesirable output: application of DEA and directional distance function [J]. Energy Policy, 2012, 44:140-152.
[13]	涂正革.环境、资源与工业增长的协调性 [J]. 经济研究, 2008,(2):93-105.
[14]	Zhou P, Ang B W, Poh K L. Slacks-based efficiency measures for modeling environmental performance [J]. Ecological Economics, 2006,(6):111-118.
[15]	王兵,吴延瑞,颜鹏飞.中国区域环境效率与环境全要素生产率增长 [J]. 经济研究, 2010,(5):95-109.
[16]	Choi Y, Zhang N, Zhou P. Efficiency and abatement costs of energy-related CO2 emissions in China: A slacks-based efficiency measure [J]. Applied Energy, 2012,(98):198-208.
[17]	Wang K, Wei Y M, Zhang X. A comparative analysis of China's regional energy and emission performance: which is the better way to deal with undesirable outputs? [J]. Energy Policy, 2012, 46:574-584.
[18]	宋马林,王舒鸿.环境规制、技术进步与经济增长 [J]. 经济研究, 2013,(3):122-134.
[19]	王兵,罗佑军.中国区域工业生产效率、环境治理效率与综合效率实证研究 [J]. 世界经济文汇, 2015,(1):99-119.
[20]	Kuosmanen T, Kortelainen M. Measuring eco-efficiency of production with DEA [J]. Journal of Industrial Ecology, 2005, 9(4):59-72.
[21]	Picazo-Tadeo A J, Gomez-Limon J A, Reig-Martinez E. Assessing farming eco-efficiency: a DEA approach [J]. Journal of Environmental Management, 2011,92:1154-1164.
[22]	Fare R, Grosskopf S. Directional distance function and slacks-based measure of efficiency [J]. European Journal of Operational Research, 2010,200(1):320-322.
[23]	Fukuyama H, Yoshida Y, Managi S. Modal choice between air and rail: a social efficiency benchmarking analysis that considers CO2 emissions [J]. Environmental Economics and Policy Studies, 2011,13(2):89-102.
[24]	Chang T P, Hu J L, Chou R Y, et al. The sources of bank productivity growth in China during 2002~2009: A disaggregation view [J]. Journal of Banking and Finance, 2012,36:1997-2006.
[25]	Kapelko M, Horta I M, Camanho A S, et al. Measurement of input-specific productivity growth with an application to the construction industry in Spain and Portugal [J]. International Journal of Production Economics, 2015,166(8):64-71.
[26]	Fare R, Grosskopf S, Lindgren B, et al. Productivity change in Swedish pharmacies 1980~1989: A non-parametric Malmquist approach [J]. Journal of Productivity Analysis, 1992,3(1/2):85-101.
[27]	Fare R, Grosskopf S, Norris M, et al. Productivity growth, technical progress and efficiency change in industrialized countries [J]. The American Economic Review, 1994,84(1):66-83.
[28]	国家统计局.中国统计年鉴 [J]. 北京:中国统计出版社, 2004-2013.
[29]	国家统计局.中国能源统计年鉴 [J]. 北京:中国统计出版社, 2004-2013.
[30]	国家统计局.中国环境统计年鉴 [J]. 北京:中国统计出版社, 2004-2013.
[31]	胡鞍钢,郑京海,高宇宁,等.考虑环境因素的省级技术效率排名:1999~2005 [J]. 经济学季刊, 2008,4(3):933-960.