Investigating spatio-temporal characteristics and influencing factors for green energy consumption in China
Xiaowei Ma, Shimei Weng, Jun Zhao, Huiling Liu, Hongyun Huang
Geoscience Frontiers ›› 2024, Vol. 15 ›› Issue (3) : 101672.
Investigating spatio-temporal characteristics and influencing factors for green energy consumption in China
The green transformation of energy consumption is beneficial for promoting green development in China. This study constructed a green energy consumption evaluation index system and measured the green energy consumption levels in 30 provinces of China from 2000 to 2019 using the fuzzy comprehensive evaluation method. This study further employed the spatial Durbin model to examine influencing factors and spillover effects of green energy consumption. The results showed that, temporally, China’s green energy consumption levels had a fluctuating upward trend. While, spatially, the overall levels of green energy consumption in China showed apparent characteristics of “high in the west and low in the east”. In terms of influencing factors, environmental regulations played an important role in promoting green energy consumption in the region, while economic development, opening up, and industrial structure had considerably inhibiting effects. Additionally, economic development, opening up, and industrial structure of neighboring regions showed marked positive spillover effects, while urbanization level and technological innovation showed substantial negative spillover effects. The regional heterogeneity test results showed that environmental regulation and industrial structure rationalization were the important factors for promoting green energy consumption in the eastern region, environmental regulation played an important driving role in the central region, and opening to the outside world and technological innovation helped improve the level of green energy consumption in the western region.
Energy green consumption / Spatial and temporal characteristics / Influencing factors / Spatial Durbin model / Regional heterogeneity
|
K. Abbas, D. Xu, S. Li, K. Baz. Health implications of household multidimensional energy poverty for women: A structural equation modeling technique. Energy Build., 234 (2021), Article 110661
|
|
Y. Cai, Z. Hu. Energy consumption in China: Spatial effects of industrial concentration, localization, and diversity. Sci. Total Environ., 852 (2022), Article 158568
|
|
J. Cai, H. Zheng, M. Vardanyan, Z. Shen. Achieving carbon neutrality through green technological progress: Evidence from China. Energy Policy, 173 (2023), Article 113397
|
|
K.Y. Chau, M. Moslehpour, Y.T. Tu, N.T. Tai, N.H. Tien, P.Q. Huy. Exploring the impact of green energy and consumption on the sustainability of natural resources: Empirical evidence from G7 countries. Renew. Energ., 196 (2022), pp. 1241-1249
|
|
P. Chen. Is the digital economy driving clean energy development?-New evidence from 276 cities in China. J. Clean. Prod., 372 (2022), Article 133783
|
|
G. Cui, S. Ren, B. Dou, F. Ning. Geothermal energy exploitation from depleted high-temperature gas reservoirs by recycling CO2: The superiority and existing problems. Geosci. Front., 12 (6) (2021), Article 101078
|
|
H. Huang, R. Mo, X. Chen. New patterns in China’s regional green development: An interval Malmquist-Luenberger productivity analysis. Struct. Chang. Econ. Dyn., 58 (2021), pp. 161-173
|
|
M. Hussain, Y. Lin, Y. Wang. Measures to achieve carbon neutrality: What is the role of energy structure, infrastructure, and financial inclusion. J. Environ. Manage., 325 (2023), Article 116457
|
|
J.P. Lesage, R.K. Pace. Spatial econometric models. M.M. Fischer, A. GetisBerlin (Eds.), Handbook of applied spatial analysis: Software tools, methods and applications, Springer (2009), pp. 355-376
|
|
B. Li, N. Haneklaus. The role of clean energy, fossil fuel consumption and trade openness for carbon neutrality in China. Energy Rep., 8 (2022), pp. 1090-1098
|
|
D. Li, L. Shen, S. Zhong, A. Elshkaki, X. Li. Spatial and temporal evolution patterns of material, energy and carbon emission nexus for power generation infrastructure in China. Resour. Conserv. Recycl., 190 (2023), Article 106775
|
|
B. Lin, Z. Li. Towards world’s low carbon development: The role of clean energy. Appl. Energy, 307 (2022), Article 118160
|
|
K. Liu, X. Liu, H. Long, D. Wang, G. Zhang. Spatial agglomeration and energy efficiency: Evidence from China’s manufacturing enterprises. J. Clean. Prod., 380 (2022), Article 135109
|
|
Q. Liu, L. Tang. Research on the accelerating effect of green finance on the transformation of energy consumption in China. Res. Int. Bus. Finance, 63 (2022), Article 101771
|
|
X. Ma, J. Xu. Impact of environmental regulation on high-quality economic development. Front. Environ. Sci., 10 (2022),
CrossRef
Google scholar
|
|
X. Ma, W. Ma, L. Zhang, Y. Shi, Y. Shang, H. Chen. The impact of green credit policy on energy efficient utilization in China. Environ. Sci. Pollut. Res., 28 (2021), pp. 52514-52528
|
|
A. Millot, N. Maïzi. From open-loop energy revolutions to closed-loop transition: What drives carbon neutrality?. Technol. Forecast. Soc. Change, 172 (2021), Article 121003
|
|
M.J. Montoya-Villalobos. Green consumption: The role of confidence and pessimism. Ecol. Econ., 205 (2023), Article 107733
|
|
X. Pan, S. Guo. Dynamic decomposition and regional differences of urban emergy ecological footprint in the Yangtze River Delta. J. Environ. Manage., 326 (2023), Article 116698
|
|
U.K. Pata, M.T. Kartal, T.S. Adebayo, S. Ullah. Enhancing environmental quality in the United States by linking biomass energy consumption and load capacity factor. Geosci. Front., 14 (3) (2023), Article 101531
|
|
M.E. Porter. America’s green strategy. Sci. Am., 264 (4) (1991), p. 168
|
|
M.A. Shojaeenia, N. Salehnia, S.S.M. Sadati. Clean to dirty energy consumption ratio, institutional quality, and welfare; an inter-continental panel quantile analysis. J. Clean. Prod., 364 (2022), Article 132703
|
|
A. Sivapalan, T. von der Heidt, P. Scherrer, G. Sorwar. A consumer values-based approach to enhancing green consumption. Sustain. Prod. Consum., 28 (2021), pp. 699-715
|
|
M. Song, S.K. Mangla, J. Wang, J. Zhao, J. An. Asymmetric information, “coal-to-gas” transition and coal reduction potential: An analysis using the nonparametric production frontier method. Energy Econ., 114 (2022), Article 106311
|
|
F. Wang, C. Zhang, W. Mbanyele, H. Huang, T. Balezentis. Revisiting the nexus between financial agglomeration and energy efficiency: A spatial spillover approach. Energy Sources, Part B: Econ. Plann. Policy, 17 (1) (2022), p. 2118902
|
|
Y. Wen, P. Hu, J. Li, Q. Liu, L. Shi, J. Ewing, Z. Ma. Does China’s carbon emissions trading scheme really work? A case study of the Hubei pilot. J. Clean. Prod., 277 (2020), Article 124151
|
|
P. Xu, M. Hussain, C. Ye, J. Wang, C. Wang, J. Geng, Y. Liu, J. Chen. Natural resources, economic policies, energy structure, and ecological footprints’ nexus in emerging seven countries. Resour. Policy, 77 (2022), Article 102747
|
|
C. Xue, M. Shahbaz, Z. Ahmed, M. Ahmad, A. Sinha. Clean energy consumption, economic growth, and environmental sustainability: what is the role of economic policy uncertainty?. Renew. Energy, 184 (2022), pp. 899-907
|
|
Y. Yu, W. Wu, T. Zhang, Y. Liu. Environmental catching-up, eco-innovation, and technological leadership in China’s pilot ecological civilization zones. Technol. Forecast. Soc. Change, 112 (2016), pp. 228-236
|
|
A. Zakari, V. Tawiah, I. Khan, R. Alvarado, G. Li. Ensuring sustainable consumption and production pattern in Africa: Evidence from green energy perspectives. Energy Policy, 169 (2022), Article 113183
|
|
Y. Zhang, B. Fu. Impact of China’s establishment of ecological civilization pilot zones on carbon dioxide emissions. J. Environ. Manage., 325 (2023), Article 116652
|
|
Q. Zhang, X. Huang, Y. Xu, M.A. Bhuiyan, P. Liu. New energy demonstration city pilot and energy green consumption: Evidences from China. Energy Reports, 8 (2022), pp. 7735-7750
|
|
Y. Zhou, S. Zou, W. Duan, Y. Chen, K. Takara, Y. Di. Analysis of energy carbon emissions from agroecosystems in Tarim River Basin, China: A pathway to achieve carbon neutrality. Appl. Energy, 325 (2022), Article 119842
|
|
T. Zou, P. Guo, Q. Wu. Spatial and temporal evolutionary characteristics and driving factors of energy green consumption levels in China: based on the perspective of social - technology system transition. Science and Technology Management Research, 42 (22) (2022), pp. 191-198 (in Chinese with English abstract)
|
/
| 〈 |
|
〉 |
AI Summary
