[2] 杨宇, 刘毅. 世界能源地理研究进展及学科发展展望. 地理科学进展, 2013,32(5):818-830. [ YANGY, LIUY. Progress and prospect of world energy geography in China. Progress in Geography, 2013,32(5):818-830.] [YANG Y, LIU Y. Progress and prospect of world energy geography in China. Progress in Geography, 2013, 32(5): 818-830.]
[3] [J]. Statistical Review of World Energy(2019).
[4] 杨宇, 王礼茂, 江东, 等. 美国对伊朗石油禁运与全球能源安全. 地理研究, 2018,37(10):1879-1898. [ YANGY, WANG LM, JIANGD, et al. U.S. sanctions policy on Iran's oil export and its influence on global energy security. Geographical Research, 2018,37(10):1879-1898.] [YANG Y, WANG L M, JIANG D, et al. U.S. sanctions policy on Iran's oil export and its influence on global energy security. Geographical Research, 2018, 37(10): 1879-1898.]
[5] 中华人民共和国国家统计局. 中国统计年鉴. 2019. [ National Bureau of Statistcs of China. China Statistical Yearbook. 2019.] [National Bureau of Statistcs of China. China Statistical Yearbook. 2019.]
[6] 石敏俊, 黄文, 李娜. 资源优势能否转化为产业优势: 煤炭开发重心西移对能源密集型产业空间格局变化的影响. 自然资源学报, 2015,30(6):891-902. [ SHI MJ, HUANGW, LIN. Can resource advantage become industrial advantage: Impact of the westward shift of coal production on the spatial pattern of energy intensive indutries in China. Journal of Natural Resources, 2015,30(6):891-902.] [SHI M J, HUANG W, LI N. Can resource advantage become industrial advantage: Impact of the westward shift of coal production on the spatial pattern of energy intensive indutries in China. Journal of Natural Resources, 2015, 30(6): 891-902.]
[7] 朱孟珏, 庄大昌, 李涛. 1990—2014年中国煤炭运输网络的时空特征研究. 自然资源学报, 2018,33(3):454-466. [ ZHU MJ, ZHUANG DC, LIT. Spatial characteristics of coal transportation network in China during 1990-2014. Journal of Natural Resources, 2018,33(3):454-466.] [ZHU M J, ZHUANG D C, LI T. Spatial characteristics of coal transportation network in China during 1990-2014. Journal of Natural Resources, 2018, 33(3): 454-466.]
[8] WANGJ, DONGY, WUJ et al. Coal production forecast and low carbon policies in China[J]. Energy Policy, 39, 5970-5979(2011).
[9] 柳君波, 高俊莲, 徐向阳. 中国煤炭供应行业格局优化及排放. 自然资源学报, 2019,34(3):473-486. [ LIU JB, GAO JL, XU XY. Pattern optimization and carbon emissions of coal supply in China. Journal of Natural Resources, 2019,34(3):473-486.] [LIU J B, GAO J L, XU X Y. Pattern optimization and carbon emissions of coal supply in China. Journal of Natural Resources, 2019, 34(3): 473-486.]
[10] LIR, LEUNGG C K. Coal consumption and economic growth in China[J]. Energy Policy, 40, 438-443(2012).
[11] 林伯强, 吴微. 中国现阶段经济发展中的煤炭需求. 中国社会科学, 2018, (2): 141-161, 207-208. [ LIN BQ, WUW. Demand for coal in current chinese economic development. Social Sciences in China, 2018, (2): 141-161, 207-208.] [LIN B Q, WU W. Demand for coal in current chinese economic development. Social Sciences in China, 2018, (2): 141-161, 207-208.]
[12] RIKER DA. International coal trade and restrictions on coal consumption[J]. Energy Economics, 34, 1244-1249(2012).
[13] STECKEL JC, EDENHOFERO, JAKOBM. Drivers for the renaissance of coal[J]. PNAS, 112, 3775-3781(2015).
[14] 林伯强, 李江龙. 环境治理约束下的中国能源结构转变: 基于煤炭和二氧化碳峰值的分析. 中国社会科学, 2015, (9):84-107, 205. [ LIN BQ, LI JL. Transformation of China's energy structure under environmental governance constraints: A peak value analysis of coal and carbon dioxide. Social Sciences in China, 2015, (9):84-107, 205.] [LIN B Q, LI J L. Transformation of China's energy structure under environmental governance constraints: A peak value analysis of coal and carbon dioxide. Social Sciences in China, 2015, (9): 84-107, 205.]
[15] SHENL, GAO TM, CHENGX. China's coal policy since 1979: A brief overview[J]. Energy Policy, 40, 274-281(2012).
[17] ANG BW, LEE SY. Decomposition of industrial energy consumption: Some methodological and application issues[J]. Energy Economics, 16, 83-92(1994).
[18] ANG BW, CHOI KH. Decomposition of aggregate energy and gas emission intensities for industry: A refined divisia index method[J]. Energy Journal, 18, 59-73(1997).
[19] ANG BW. The LMDI approach to decomposition analysis: A practical guide[J]. Energy Policy, 33, 867-871(2005).
[20] 王长建, 汪菲, 张虹鸥. 新疆能源消费碳排放过程及其影响因素: 基于扩展的Kaya恒等式. 生态学报, 2016,36(8):2151-2163. [ WANG CJ, WANGF, ZHANG HO. The process of energy-related carbon emissions and influencing mechanism research in Xinjiang. Acta Ecologica Sinica, 2016,36(8):2151-2163.] [WANG C J, WANG F, ZHANG H O. The process of energy-related carbon emissions and influencing mechanism research in Xinjiang. Acta Ecologica Sinica, 2016, 36(8): 2151-2163.]
[21] 何则, 杨宇, 宋周莺, 等. 中国能源消费与经济增长的相互演进态势及驱动因素. 地理研究, 2018,37(8):1528-1540. [ HEZ, YANGY, SONG ZY, et al. The mutual evolution and driving factors of China's energy consumption and economic growth. Geographical Research, 2018,37(8):1528-1540.] [HE Z, YANG Y, SONG Z Y, et al. The mutual evolution and driving factors of China's energy consumption and economic growth. Geographical Research, 2018, 37(8): 1528-1540.]
[22] 王长建, 张小雷, 张虹鸥, 等. 基于IO-SDA模型的新疆能源消费碳排放影响机理分析. 地理学报, 2016,71(7):1105-1118. [ WANG CJ, ZHANG XL, ZHANG HO, et al. Influencing mechanism of energy-related carbon emissions in Xinjiang based on the input-output and structural decomposition analysis. Acta Geographica Sinica, 2016,71(7):1105-1118.] [WANG C J, ZHANG X L, ZHANG H O, et al. Influencing mechanism of energy-related carbon emissions in Xinjiang based on the input-output and structural decomposition analysis. Acta Geographica Sinica, 2016, 71(7): 1105-1118.]
[23] DIETZENBACHERE, LOSB. Structural decomposition techniques: Sense and sensitivity[J]. Economics Systems Research, 10, 307-324(1998).
[24] WANGC, WANGF, ZHANGX et al. Influencing mechanism of energy-related carbon emissions in Xinjiang based on the input-output and structural decomposition analysis[J]. Journal of Geographical Sciences, 27, 365-384(2017).
[25] WANGC, WANGF, ZHANGX et al. Analysis of influence mechanism of energy-related carbon emissions in Guangdong: Evidence from regional China based on the input-output and structural decomposition analysis[J]. Environmental Science and Pollution Research, 24, 25190-25203(2017).
[27] LEONTIEFW. Quantitative input and output relations in the economic systems of the United States[J]. The Review of Economics and Statistics, 18, 105-125(1936).
[28] 贺灿飞, 王俊松. 经济转型与中国省区能源强度研究. 地理科学, 2009,29(4):461-469. [ HE CF, WANG JS. Economic transition and energy intensity in China. Scientia Geographica Sinica, 2009,29(4):461-469.] [HE C F, WANG J S. Economic transition and energy intensity in China. Scientia Geographica Sinica, 2009, 29(4): 461-469.]
[29] 刘卫东, 唐志鹏, 夏炎, 等. 中国碳强度关键影响因子的机器学习识别及其演进. 地理学报, 2019,74(12):2592-2603. [ LIU WD, TANG ZP, XIAY, et al. Identifying the key factors influencing Chinese carbon intensity using machine learning, the random forest algorithm, and evolutionary analysis. Acta Geographica Sinica, 2019,74(12):2592-2603.] [LIU W D, TANG Z P, XIA Y, et al. Identifying the key factors influencing Chinese carbon intensity using machine learning, the random forest algorithm, and evolutionary analysis. Acta Geographica Sinica, 2019, 74(12): 2592-2603.]
[30] 陆大道. 中速增长: 中国经济的可持续发展. 地理科学, 2015,35(10):1207-1219. [ LU DD. Moderate-speed growth: Sustainable development of China's economy. Scientia Geographica Sinica, 2015,35(10):1207-1219.] [LU D D. Moderate-speed growth: Sustainable development of China's economy. Scientia Geographica Sinica, 2015, 35(10): 1207-1219.]
[33] 贺灿飞, 陈航航. 参与全球生产网络与中国出口产品升级. 地理学报, 2017,72(8):1331-1346. [ HE CF, CHEN HH. Participation in global production networks and export product upgrading. Acta Geographica Sinica, 2017,72(8):1331-1346.] [HE C F, CHEN H H. Participation in global production networks and export product upgrading. Acta Geographica Sinica, 2017, 72(8): 1331-1346.]
[34] WANGC, WANGF. China can lead on climate change[J]. Science, 357, 764(2017).
[35] LEQ, KORSBAKKEN JI, WILSONC et al. Drivers of declining CO2 emissions in 18 developed economies[J]. Nature Climate Change, 9, 213-217(2019).
[36] [J]. Global Energy & CO2 Status Report 2018: The latest trends in energy and emissions in 2018(2019).
