Abstract
The distribution of pollution-intensive industries is a serious challenge to environmental governance of China during the transition period. However, existing studies lack the attention to the distribution and driving factors of air-pollution-intensive industries (APIIs). Therefore, based on geospatial analysis and spatial measurement models, this study explored the spatial distribution of APIIs and their socioeconomic driving factors in Zhejiang Province from 2006 to 2018. The results show that (1) the output value of APIIs in Zhejiang showed a trend of first increasing and then slowly decreasing, indicating the industry structure has a tendency toward improvement; (2) the spatial agglomeration of APIIs in Zhejiang Province has a positive spatial correlation (significant at least at the level of 10%), and the main agglomeration areas are located in cities around Hangzhou Bay, but the overall level of agglomeration is decreasing and shows a certain diffusion trend. (3) APIIs in Zhejiang Province have significant industry differences. Industries with a high degree of concentration are mainly petroleum processing, coking, nuclear fuel processing, chemical fiber manufacturing and textile, all with the Gini coefficient exceeding 0.5. (4) The improvement of labor force, capital investment, international trade level and infrastructure level will aggravate the distribution of APIIs, while technological innovation, environmental regulation and foreign investment can effectively suppress and reduce the output value of regional APIIs. In particular, for every 1% increase in technological innovation, the output value of APIIs will decrease by 0.113%, and it will also have a significant reduction effect on neighboring cities. In the future, Zhejiang needs to fully rely on technological innovation capabilities to drive the development of green industries and the upgrading of traditional manufacturing industries.
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Data availability
The datasets used and/or analyzed under the current study are available from the corresponding author on reasonable request.
References
Bagayev, I., & Lochard, J. (2017). EU air pollution regulation: A breath of fresh air for Eastern European polluting industries? Journal of Environmental Economics and Management, 83, 145–163
Balsalobre-Lorente, D., Gokmenoglu, K. K., Taspinar, N., & Cantos-Cantos, J. M. (2019). An approach to the pollution haven and pollution halo hypotheses in MINT countries. Environmental Science and Pollution Research, 26(22), 23010–23026
Banerjee, S., Hazra, S., Khan, M. A., & Ul Husnain, M. I. (2021). Investigating India’s pollution-intensive ‘dirty’ trade specialisation: Analysis with ‘revealed symmetric comparative advantage’ index. Environmental Science and Pollution Research. https://doi.org/10.1007/s11356-021-12790-4
Becker, R., & Henderson, V. (2000). Effects of air quality regulations on polluting industries. Journal of Political Economy, 18(2), 379–421
Birdsall, N., & Wheeler, D. (1993). Trade policy and industrial pollution in Latin America: Where are the pollution havens? The Journal of Environment & Development, 2(1), 137–149
Cole, M. A., & Elliott, R. J. R. (2003). Determining the trade-environment composition effect: the role of capital, labor and environmental regulations. Journal of Environmental Economics and Management, 46(3), 363–383
Cole, M. A., Elliott, R. J., & Shimamoto, K. (2005). Industrial characteristics, environmental regulations and air pollution: an analysis of the UK manufacturing sector. Journal of Environmental Economics and Management, 50(1), 121–143
Conrad, K. (1993). Taxes and subsidies for pollution-intensive industries as trade policy. Journal of Environmental Economics and Management, 25(2), 121–135
Ding, L., Chen, K., Hua, Y., Dong, H., & Wu, A. (2020). Investigating the relationship between the industrial structure and atmospheric environment by an integrated system: A case study of Zhejiang. China. Sustainability, 12(3), 1278
Ding, L., Liu, C., Chen, K., Huang, Y., & Diao, B. (2017). Atmospheric pollution reduction effect and regional predicament: An empirical analysis based on the Chinese provincial NOx emissions. Journal of Environmental Management, 196, 178–187
Dong, F., & Liu, Y. (2020). Policy evolution and effect evaluation of new-energy vehicle industry in China. Resources Policy, 67, 101655
Dong, F., Yu, B., & Pan, Y. (2019). Examining the synergistic effect of CO2 emissions on PM2.5 emissions reduction: Evidence from China. Journal of Cleaner Production, 223, 759–771
Dong, L., Dong, H., Fujita, T., Geng, Y., & Fujii, M. (2015). Cost-effectiveness analysis of China’s sulfur dioxide control strategy at the regional level: Regional disparity, inequity and future challenges. Journal of Cleaner Production, 90, 345–359
Dong, Z., Gao, J., Yan, X., Hao, C., & Ge, C. (2017). Assessment of socio-economic impacts of the air pollution prevention and control action plan in China’s three key regions. Environmental Science Research, 30(3), 380–388
Dou, J., & Han, X. (2019). How does the industry mobility affect pollution industry transfer in China: Empirical test on pollution haven hypothesis and porter hypothesis. Journal of Cleaner Production, 217, 105–115
Du, W., & Jiang, H. (2017). “Two mountains” theory: Major proposition, major breakthrough and major innovation. Environmental Protection, 45(19), 34–38
Du, W., & Li, M. (2020). Influence of environmental regulation on promoting the low-carbon transformation of China’s foreign trade: Based on the dual margin of export enterprise. Journal of Cleaner Production, 244, 118687
Ederington, J., Levinson, A., & Minier, J. (2004). Trade liberalization and pollution havens. Advances in Economic Analysis and Policy, 3(2), 1–24
Elhorst, J. P. (2014). Matlab software for spatial panels. International Regional Science Review, 37(3), 389–405
Feng, Y. C., Wang, X. H., Du, W. C., Wu, H. Y., & Wang, J. T. (2019). Effects of environmental regulation and FDI on urban haze pollution in China: A spatial Durbin econometric analysis. Journal of Cleaner Production, 235, 210–224
Fujii, H., & Managi, S. (2016). Economic development and multiple air pollutant emissions from the industrial sector. Environmental Science and Pollution Research, 23(3), 2802–2812
Grether, J. M., Mathys, N. A., & De Melo, J. (2012). Unravelling the worldwide pollution haven effect. The Journal of International Trade & Economic Development, 21(1), 131–162
Han, F., & Xie, R. (2017). Does the agglomeration of producer services reduce carbon emissions? The Journal of Quantitative & Technical Economics, 03, 41–59
He, C., Huang, Z., & Ye, X. (2014). Spatial heterogeneity of economic development and industrial pollution in urban China. Stochastic Environmental Research and Risk Assessment, 28(4), 767–781
He, C., Wei, Y. D., & Xie, X. (2008). Globalization, institutional change, and industrial location: Economic transition and industrial concentration in China. Regional Studies, 42(7), 923–945
Hu, J., Liu, Y., Fang, J., Jing, Y., Liu, Y., & Liu, Y. (2019). Characterizing pollution-intensive industry transfers in China from 2007 to 2016 using land use data. Journal of Cleaner Production, 223, 424–435
Ikeda, K., Murota, K., Akamatsu, T., & Takayama, Y. (2017). Agglomeration patterns in a long narrow economy of a new economic geography model: Analogy to a racetrack economy. International Journal of Economic Theory, 13(1), 113–145
Jaffe, A. B., Peterson, S. R., Portney, P. R., & Stavins, R. N. (1995). Environmental regulations and the competitiveness of U.S. manufacturing: What does the evidence tell us? Journal of Economic Literature, 33(1), 132–163
Jiang, B., Ding, L., & Fang, X. (2019). Sustainable Development of new urbanization from the perspective of coordination: A new complex system of urbanization-technology innovation and the atmospheric environment. Atmosphere, 10(11), 652
Keller, W., & Levinson, A. (2002). Pollution abatement costs and foreign direct investment inflows to U.S. states. Review of Economics and Statistics, 84(4), 691–703
Khan, J., Kakosimos, K., Jensen, S. S., Hertel, O., Sørensen, M., Gulliver, J., & Ketzel, M. (2020). The spatial relationship between traffic-related air pollution and noise in two Danish cities: Implications for health-related studies. Science of the Total Environment, 726, 138577
Kim, S. (1995). Expansion of markets and the geographic distribution of economic activities: The trends in US regional manufacturing structure, 1860–1987. The Quarterly Journal of Economics, 110(4), 881–908
Konisky, D. M. (2009). Assessing US state susceptibility to environmental regulatory competition. State Politics & Policy Quarterly, 9(4), 404–428
Lanoie, P., Laurent-Lucchetti, J., Johnstone, N., & Ambec, S. (2011). Environmental policy, innovation and performance: New insights on the Porter hypothesis. Journal of Economics & Management Strategy, 20(3), 803–842
LeSage, J. P. (2008). An introduction to spatial econometrics. Revue D’économie Industrielle, 123, 19–44
Li, L., Wang, J., Tan, Z., Ge, X., Zhang, J., & Yun, X. (2014). Policies for eliminating low-efficiency production capacities and improving energy efficiency of energy-intensive industries in China. Renewable and Sustainable Energy Reviews, 39, 312–326
Li, X., Hui, E. C. M., Lang, W., Zheng, S., & Qin, X. (2020). Transition from factor-driven to innovation-driven urbanization in China: A study of manufacturing industry automation in Dongguan City. China Economic Review, 59, 101382
Lian, T., Ma, T., Cao, J., & Wu, Y. (2016). The effects of environmental regulation on the industrial location of China’s manufacturing. Natural Hazards, 80(2), 1381–1403
Liu, H., & Song, Y. (2020). Financial development and carbon emissions in China since the recent world financial crisis: Evidence from a spatial-temporal analysis and a spatial Durbin model. Science of the Total Environment, 715, 136771
Liu, N., Sun, Y., Tang, J., & Du, J. (2019). The environmental effects of pollution-intensive industry agglomeration based on the perspective of spatial spillover. Acta Scientiae Circumstantiae, 39(7), 2442–2454
Liu, Q., Wang, S., Zhang, W., Zhan, D., & Li, J. (2018). Does foreign direct investment affect environmental pollution in China’s cities? A spatial econometric perspective. Science of the Total Environment, 613, 521–529
Lu, Y. Y., He, Y., Wang, B., Ye, S. S., Hua, Y., & Ding, L. (2019). Efficiency evaluation of atmospheric pollutants emission in Zhejiang Province China: A DEA-Malmquist based approach. Sustainability, 11(17), 4544
Mele, M., & Magazzino, C. (2020). A machine learning analysis of the relationship among iron and steel industries, air pollution, and economic growth in China. Journal of Cleaner Production, 277, 123293
Muhammad, S., Long, X., Salman, M., & Dauda, L. (2020). Effect of urbanization and international trade on CO2 emissions across 65 belt and road initiative countries. Energy, 196, 117102
Mulatu, A., Gerlagh, R., Rigby, D., & Wossink, A. (2010). Environmental regulation and industry location in Europe. Environmental and Resource Economics, 45(4), 459–479
Nadeem, A. M., Ali, T., Khan, M. T., & Guo, Z. (2020). Relationship between inward FDI and environmental degradation for Pakistan: an exploration of pollution haven hypothesis through ARDL approach. Environmental Science and Pollution Research, 27, 1–19
NBSC (National Bureau of Statistics of China). (2007–2018). China city statistical yearbook. Beijing: Chinese Statistics Press.
Porter, M. E., & Van der Linde, C. (1995). Toward a new conception of the environment-competitiveness relationship. Journal of Economic Perspectives, 9(4), 97–118
Qiu, F., Jiang, T., Zhang, C., & Shan, Y. (2013). Spatial relocation and mechanism of pollution-intensive industries in Jiangsu Province. Geographic Sciences Sinca, 33(7), 789–796
Ren, L., Cui, E., & Sun, H. (2014). Temporal and spatial variations in the relationship between urbanization and water quality. Environmental Science and Pollution Research, 21(23), 13646–13655
Richard, D. M., William, A. P., & Jhih-Shyang, S. (2002). Jobs versus the environment: An industry-level perspective. Journal of Environmental Economics and Management, 43(3), 412–436
Shao, S., Li, X., Cao, J., & Yang, L. (2016). China’s economic policy choices for governing smog pollution based on spatial spillover effects. Economics Research Journal, 51(9), 73–88
Shen, J., Wang, S., Liu, W., & Chu, J. (2019). Does migration of pollution-intensive industries impact environmental efficiency? Evidence supporting “Pollution Haven Hypothesis.” Journal of Environmental Management, 242, 142–152
Shen, J., Wei, Y. D., & Yang, Z. (2012). The impact of environmental regulations on the location of pollution-intensive industries in china. Journal of Cleaner Production, 148, 785–794
Shen, J., Xiang, C., & Liu, Y. (2017). The mechanism of pollution-intensive industry relocation in Guangdong Province, 2000–2009. Geographical Research, 31(2), 357–368
Su, Y., & Yu, Y. (2020). Spatial agglomeration of new energy industries on the performance of regional pollution control through spatial econometric analysis. Science of the Total Environment, 704, 135261
Tian, G., Miao, C., Hu, Z., & Miao, J. (2018). Environmental regulation, local protection and the spatial distribution of pollution-intensive industries in China. Acta Geographica Sinica, 73(10), 1954–1969
Tobey, J. A. (1990). The effects of domestic environmental policies on patterns of world trade: An empirical test. Kyklos, 43(2), 191–209
Twerefou, D. K., Akpalu, W., & Mensah, A. C. E. (2019). Trade-induced environmental quality: The role of factor endowment and environmental regulation in Africa. Climate and Development, 11(9), 786–798
Verhoef, E. T., & Nijkamp, P. (2002). Externalities in urban sustainability: Environmental versus localization-type agglomeration externalities in a general spatial equilibrium model of a single-sector monocentric industrial city. Ecological Economics, 40(2), 157–179
Wang, F., Dong, S., Mao, Q., Huang, Y., & Li, J. (2014). Analysis of the environment-pollution bias of industrial structure in areas along the Yellow River in Ningxia and Inner Mongolia. Resources Science, 36(3), 0620–0631
Wang, H., Dong, C., & Liu, Y. (2019a). Beijing direct investment to its neighbors: A pollution haven or pollution halo effect? Journal of Cleaner Production, 239, 118062
Wang, L., & Shen, J. (2017). Comparative analysis of urban competitiveness in the Yangtze River Delta and Pearl River Delta regions of China, 2000–2010. Applied Spatial Analysis and Policy, 10(3), 401–419
Wang, S., He, Y., & Song, M. (2021). Global value chains, technological progress, and environmental pollution: Inequality towards developing countries. Journal of Environmental Management, 277, 110999
Wang, W., Yua, J., Cui, Y., He, J., Xue, P., Cao, W., et al. (2018). Characteristics of fine particulate matter and its sources in an industrialized coastal city, Ningbo, Yangtze River Delta, China. Atmospheric Research, 203, 105–117
Wang, Y., Cao, X., Cheng, Y., & Ren, J. (2019b). Spatio-temporal evolution and influencing mechanism of pollution-intensive industries in Shandong Province. Economic Geography, 39(1), 130–139
Wei, D., Liu, Y., & Zhang, N. (2019). Does industry upgrade transfer pollution: Evidence from a natural experiment of Guangdong province in China. Journal of Cleaner Production, 229, 902–910
Wu, J., Wei, Y. D., Chen, W., & Yuan, F. (2019). Environmental regulations and redistribution of polluting industries in transitional China: Understanding regional and industrial differences. Journal of Cleaner Production, 206, 142–155
Xia, H., Ding, L., Yang, S., & Wu, A. (2020). Socioeconomic factors of industrial air pollutants in Zhejiang Province, China: Decoupling and decomposition analysis. Environmental Science and Pollution Research, 27, 28247–28266
Xie, Q., & Sun, Q. (2020). Assessing the impact of FDI on PM2.5 concentrations: A nonlinear panel data analysis for emerging economies. Environmental Impact Assessment Review, 80, 106314
Xu, B., Song, W., Gao, X., & Zhang, Y. (2019). Research on the science and technology policy coordination of China’s Yangtze River Delta. American Journal of Industrial and Business Management, 9(4), 875
Yang, X., Jiang, P., & Pan, Y. (2020). Does China’s carbon emission trading policy have an employment double dividend and a Porter effect? Energy Policy, 142, 111492
Zhang, G., Liu, W., & Duan, H. (2020a). Environmental regulation policies, local government enforcement and pollution-intensive industry transfer in China. Computers & Industrial Engineering, 148, 106748
Zhang, J., Wang, Y., Huang, B., Li, Y., & Song, D. (2015). Spatial agglomeration and regional shift of pollution-intensive industries in China. Journal of Industrial and Economics, 8, 3–11
Zhang, K., Shao, S., & Fan, S. (2020b). Market integration and environmental quality: Evidence from the Yangtze river delta region of China. Journal of Environmental Management, 261, 110208
Zhang, X., Zhao, W., Nie, L., Shao, X., Dang, H., Zhang, W., & Wang, D. (2021). A new classification approach to enhance future VOCs emission policies: Taking solvent-consuming industry as an example. Environmental Pollution, 268, 115868
Zhang, Z., Cheng, H., & Yu, Y. (2020c). Relationships among government funding, R&D model and innovation performance: A study on the Chinese textile industry. Sustainability, 12(2), 644
Zhao, H., Liu, Y., Lindley, S., Meng, F., & Niu, M. (2020). Change, mechanism, and response of pollutant discharge pattern resulting from manufacturing industrial transfer: A case study of the Pan-Yangtze River Delta China. Journal of Cleaner Production, 244, 118587
Zheng, D., & Shi, M. (2017). Multiple environmental policies and pollution haven hypothesis: Evidence from China’s polluting industries. Journal of Cleaner Production, 141, 295–304
Zheng, J., Jiang, P., Qiao, W., Zhu, Y., & Kennedy, E. (2016). Analysis of air pollution reduction and climate change mitigation in the industry sector of Yangtze River Delta in China. Journal of Cleaner Production, 114, 314–322
Zhou, X., He, C., & Liu, Y. (2015). An empirical study on the geographical distribution of pollution-intensive industries in China. Journal of Natural Resources, 30(7), 1183–1196
Zhou, Y., Zhu, S., & He, C. (2017). How do environmental regulations affect industrial dynamics? Evidence from China’s pollution-intensive industries. Habitat International, 60, 10–18
Zhu, S., He, C., & Liu, Y. (2014). Going green or going away: environmental regulation, economic geography and firms’ strategies in China’s pollution-intensive industries. Geoforum, 55, 53–65
Zou, H., Duan, X., Zhao, H., & Wang, L. (2016). Spatial evolution of pollution-intensive industries and its effects on pollution emissions in Yangtze River Delta. Journal of University of the Chinese Academy of Sciences, 33(5), 703–710
ZPBS (Zhejiang Provincial Bureau of Statistics). (2007–2018a). Zhejiang statistical yearbook. Beijing: China Statistics Press.
ZPBS (Zhejiang Provincial Bureau of Statistics). (2007–2018b). Zhejiang natural resources and environment statistical yearbook. Beijing: China Statistics Press.
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This work was supported by the Major Humanities and Social Science Projects of Colleges in Zhejiang Province in 2019–2020 (2021GH047). Special thanks to the second author of this paper, my dearest wife. This manuscript is also the best gift for the twelfth anniversary of our love, for our efforts to explore the common direction together.
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Ding, L., Fang, X. Spatial–temporal distribution of air-pollution-intensive industries and its social-economic driving mechanism in Zhejiang Province, China: a framework of spatial econometric analysis. Environ Dev Sustain 24, 1681–1712 (2022). https://doi.org/10.1007/s10668-021-01503-z
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DOI: https://doi.org/10.1007/s10668-021-01503-z