Digital Economy Development, Common Prosperity, and Carbon Emissions: An Empirical Study in China
Abstract
:1. Introduction
2. Literature Review
2.1. Research on Digital Economy
2.2. Research on Carbon Emissions
3. Mechanistic Theory of Analysis and Hypothetical Research
3.1. The Digitally Based Economic Impacts on Carbon Emissions
3.2. The Digitally Based Economy’s Impacts on Carbonic Discharge through Its Effect on Common Prosperity
3.3. The Spatial Spillover Effects of the Digitally Based Economic Impacts on Carbonic Emissions
4. Model and Data
4.1. Variable Description
4.1.1. Explained Variables
4.1.2. Explanatory Variables
4.1.3. Intermediary Variable
4.1.4. Control Variables
4.2. Model Construction
4.3. Data Sources
5. Empirical Results and Analyses
5.1. Analysis of Baseline Regression Results
5.2. Endogeneity Test
5.3. Robustness Test
5.3.1. Replace the Variables That Are Core Explanatory
5.3.2. Replace the Explained Variable
5.3.3. Replacement Sample Period
6. Discussion
6.1. Analysis of Intermediary Mechanisms
6.2. Spatial Spillover Analysis of Effects
6.3. Heterogeneity Analysis
6.3.1. Heterogeneity in Different Regions
6.3.2. Heterogeneity in Levels of Economic Development
7. Conclusions and Policy Implications
7.1. Conclusions
7.2. Policy Implications
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
- Abbas, Hafiz Syed Mohsin, Xiao dong Xu, and Chun xia Sun. 2021. Role of foreign direct investment interaction to energy consumption and institutional governance in sustainable GHG emission reduction. Environmental Science and Pollution Research 28: 56808–21. [Google Scholar] [CrossRef] [PubMed]
- Adner, Ron, Phanish Puranam, and Feng Zhu. 2019. What Is Different About Digital Strategy? From Quantitative to Qualitative Change. Strategy Science 4: 253–61. [Google Scholar] [CrossRef]
- Ahmed, Zahoor, Mahmood Ahmad, Muntasir Murshed, Muhammad Ibrahim Shah, Haider Mahmood, and Shujaat Abbas. 2022. How do green energy technology investments, technological innovation, and trade globalization enhance green energy supply and stimulate environmental sustainability in the G7 countries? Gondwana Research 112: 105–15. [Google Scholar] [CrossRef]
- Alam, Naushad, Nazia Iqbal Hashmi, Syed Ahsan Jamil, Muntasir Murshed, Haider Mahmood, and Shabbir Alam. 2022. The marginal effects of economic growth, financial development, and low-carbon energy use on carbon footprints in Oman: Fresh evidence from autoregressive distributed lag model analysis. Environmental Science and Pollution Research 29: 76432–45. [Google Scholar] [CrossRef]
- Awan, Ashar, Kashif Raza Abbasi, Soumen Rej, Arunava Bandyopadhyay, and Kangjuan Lv. 2022. The impact of renewable energy, internet use and foreign direct investment on carbon dioxide emissions: A method of moments quantile analysis. Renewable Energy 189: 454–66. [Google Scholar] [CrossRef]
- Bai, Ling, Tianran Guo, Wei Xu, Yaobin Liu, Ming Kuang, and Lei Jiang. 2023. Effects of digital economy on carbon emission intensity in Chinese cities: A life-cycle theory and the application of non-linear spatial panel smooth transition threshold model. Energy Policy 183: 113792. [Google Scholar] [CrossRef]
- CAICT. 2020. White Paper on China’s Digital Economy Development 2020. Beijing: China Academy of Information and Communications Technology. [Google Scholar]
- Chen, Guifu, Jing Han, and Hongwei Yuan. 2022. Urban digital economy development, enterprise innovation, and ESG performance in China. Frontiers in Environmental Science 10: 955055. [Google Scholar] [CrossRef]
- Chen, Lijuan. 2021. How CO2 emissions respond to changes in government size and level of digitalization? Evidence from the BRICS countries. Environmental Science and Pollution Research 29: 457–67. [Google Scholar] [CrossRef] [PubMed]
- Chen, Li, and Yuanbo Zhang. 2023. Does the development of the digital economy promote common prosperity?—Analysis based on 284 cities in China. Sustainability 15: 4688. [Google Scholar] [CrossRef]
- Chen, Pengyu. 2022. Is the digital economy driving clean energy development? -New evidence from 276 cities in China. Journal of Cleaner Production 372: 133783. [Google Scholar] [CrossRef]
- Chen, Wen, and Ying Wu. 2022. Does intellectual property protection stimulate digital economy development? Journal of Applied Economics 25: 723–30. [Google Scholar] [CrossRef]
- Chen, Yu, and Boqiang Lin. 2021. Understanding the green total factor energy efficiency gap between regional manufacturing—Insight from infrastructure development. Energy 237: 121553. [Google Scholar] [CrossRef]
- Cheng, Yue, Yue Zhang, Jingjing Wang, and Jinxing Jiang. 2023. The impact of the urban digital economy on China’s carbon intensity: Spatial spillover and mediating effect. Conservation and Recycling 189: 106762. [Google Scholar] [CrossRef]
- Cheng, Zhonghua, Lianshui Li, and Jun Liu. 2018. Industrial structure, technical progress and carbon intensity in China’s provinces. Renewable and Sustainable Energy Reviews 81: 2935–46. [Google Scholar] [CrossRef]
- Dong, Kangyin, Renjin Sun, Hongdian Jiang, and Xiangang Zeng. 2018. CO2 emissions, economic growth, and the environmental Kuznets curve in China: What roles can nuclear energy and renewable energy play? Journal of Cleaner Production 196: 51–63. [Google Scholar] [CrossRef]
- Elhorst, J. Paul. 2010. Applied Spatial Econometrics: Raising the Bar. Spatial Economic Analysis 5: 9–28. [Google Scholar] [CrossRef]
- Fernández-Portillo, Antonio, Manuel Almodóvar-González, and Ricardo Hernández-Mogollón. 2020. Impact of ICT development on economic growth. A study of OECD European union countries. Technology in Society 63: 101420. [Google Scholar] [CrossRef]
- Godil, Danish I., Zhang Yu, Arshian Sharif, Rimsha Usman, and Syed Abdul Rehman Khan. 2021. Investigate the role of technology innovation and renewable energy in reducing transport sector CO2 emission in China: A path toward sustainable development. Sustainable Development 29: 694–707. [Google Scholar] [CrossRef]
- Guo, Qingran, Zhou Wu, Atif Jahanger, Cuicui Ding, Bocheng Guo, and Ashar Awan. 2022. The spatial impact of digital economy on energy intensity in China in the context of double carbon to achieve the sustainable development goals. Environmental Science and Pollution Research International 30: 35528–44. [Google Scholar] [CrossRef]
- Han, Ying, Xiaoyuan Qi, and Yuanfan Yang. 2020. Analysis of the spillover effect of energy intensity among provinces in China based on space-time lag model. Environmental Science and Pollution Research 27: 16950–62. [Google Scholar] [CrossRef]
- Huang, Junbing, Yajun Wang, Bingjiang Luan, Hong Zou, and Jun Wang. 2023. The energy intensity reduction effect of developing digital economy: Theory and empirical evidence from China. Energy Economics 128: 107193. [Google Scholar] [CrossRef]
- Kamal, Mustafa, Muhammad Usman, Atif Jahanger, and Daniel Balsalobre-Lorente. 2021a. Revisiting the role of fiscal policy, financial development, and foreign direct investment in reducing environmental pollution during globalization mode: Evidence from linear and nonlinear panel data approaches. Energies 14: 6968. [Google Scholar] [CrossRef]
- Khan, Samiha, Muntasir Murshed, Ilhan Ozturk, and Khurshid Khudoykulov. 2022a. The roles of energy efficiency improvement, renewable electricity production, and financial inclusion in stimulating environmental sustainability in the Next Eleven countries. Renewable Energy 193: 1164–76. [Google Scholar] [CrossRef]
- Khan, Yasir, Hana Oubaih, and Fatima Zahra Elgourrami. 2022b. The effect of renewable energy sources on carbon dioxide emissions: Evaluating the role of governance, and ICT in Morocco. Renewable Energy 190: 752–63. [Google Scholar] [CrossRef]
- Kong, Haojia, Lifan Shi, Dan Da, Zhijiang Li, Decai Tang, and Wei Xing. 2022. Simulation of China’s Carbon Emission based on Influencing Factors. Energies 15: 3272. [Google Scholar] [CrossRef]
- Li, Wenjing, Xiaozhong Yu, Nan Hu, Fan Huang, Jing Wang, and Qingnan Peng. 2022. Study on the relationship between fossil energy consumption and carbon emission in Sichuan Province. Energy Reports 8: 53–62. [Google Scholar] [CrossRef]
- Li, Xiaoyan, Jia Liu, and Peijie Ni. 2021a. The impact of the digital economy on CO2 emissions: A theoretical and empirical analysis. Sustainability 13: 7267. [Google Scholar] [CrossRef]
- Li, Zhiguo, and Jie Wang. 2022a. Spatial spillover effect of carbon emission trading on carbon emission reduction: Empirical data from pilot regions in China. Energy 251: 123906. [Google Scholar] [CrossRef]
- Li, Zhiguo, and Jie Wang. 2022b. The dynamic impact of digital economy on carbon emission reduction: Evidence city-level empirical data in China. Journal of Cleaner Production 351: 131570. [Google Scholar] [CrossRef]
- Li, Zihanxin, Nuoyan Li, and Huwei Wen. 2021b. Digital Economy and Environmental Quality: Evidence from 217 Cities in China. Sustainability 13: 8058. [Google Scholar] [CrossRef]
- Lin, Boqiang, and Xuehui Li. 2011. The effect of carbon tax on per capita CO2 emissions. Energy Policy 39: 5137–46. [Google Scholar] [CrossRef]
- Liu, Da, Linlin Xu, Umma Habiba Sadia, and Hui Wang. 2021a. Evaluating the CO2 emission reduction effect of China’s battery electric vehicle promotion efforts. Atmospheric Pollution Research 12: 101115. [Google Scholar] [CrossRef]
- Liu, Yonghong, Chaochao Gao, and Yingying Lu. 2017. The impact of urbanization on GHG emissions in China: The role of population density. Journal of Cleaner Production 157: 299–309. [Google Scholar] [CrossRef]
- Liu, Yang, Kangyin Dong, Jianda Wang, and Farhad Taghizadeh-Hesary. 2023. Towards sustainable development goals: Does common prosperity contradict carbon reduction? Economic Analysis and Policy 79: 70–88. [Google Scholar] [CrossRef]
- Liu, Yun, Meng Liu, Gege Wang, Lulu Zhao, and Pan An. 2021b. Effect of Environmental Regulation on High-quality Economic Development in China-An Empirical Analysis Based on Dynamic Spatial Durbin Model. Environmental Science and Pollution Research 28: 54661–78. [Google Scholar] [CrossRef]
- Llopis-Albert, Carlos, Francisco Rubio, and Francisco Valero. 2021. Impact of digital transformation on the automotive industry. Technological Forecasting and Social Change 162: 120343. [Google Scholar] [CrossRef]
- Ma, Dan, and Qing Zhu. 2022. Innovation in emerging economies: Research on the digital economy driving high-quality green development. Journal of Business Research 145: 801–13. [Google Scholar] [CrossRef]
- Ma, Qiang, Muhammad Tariq, Haider Mahmood, and Zeeshan Khan. 2022. The nexus between digital economy and carbon dioxide emissions in China: The moderating role of investments in research and development. Technology in Society 68: 101910. [Google Scholar] [CrossRef]
- Mohsin, Muhammad, Han Phoumin, Ik Joong Youn, and Farhad Taghizadeh-Hesary. 2021. Enhancing energy and environmental efficiency in the power sectors: A case study of Singapore and China. Journal of Environmental Assessment Policy and Management 23: 2250018. [Google Scholar] [CrossRef]
- Nicolay, John. 1999. The digital economy: Promise and peril in the age of networked intelligence. Journal of Policy Analysis and Management 18: 156–68. [Google Scholar]
- Ozturk, Ilhan, and Sana Ullah. 2022. Does digital financial inclusion matter for economic growth and environmental sustainability in OBRI economies? An empirical analysis. Resources, Conservation and Recycling 185: 106489. [Google Scholar] [CrossRef]
- Pang, Silu, Guihong Hua, and Hui Liu. 2023. How do R&D capital market distortions affect innovation efficiency in China? Some evidence about spatial interaction and spillover effects. Socio-Economic Planning Sciences 90: 101739. [Google Scholar]
- Pata, Ugur Korkut, and Cem Isik. 2021. Determinants of the load capacity factor in China: A novel dynamic ARDL approach for ecological footprint accounting. Resources Policy 74: 102313. [Google Scholar] [CrossRef]
- Pata, Ugur Korkut, Sinan Erdogan, and Oktay Ozkan. 2023. Is reducing fossil fuel intensity important for environmental management and ensuring ecological efficiency in China? Journal of Environmental Management 329: 117080. [Google Scholar] [CrossRef]
- Ren, Siyu, Y. Hao, Lu Xu, Haitao Wu, and Ning Ba. 2021. Digitalization and energy: How does internet development affect China’s energy consumption? Energy Economics 98: 105220. [Google Scholar] [CrossRef]
- Shi, Xiuyi, Yingzhi Xu, and Wenyuan Sun. 2023. Evaluating China’s pilot carbon Emission Trading Scheme: Collaborative reduction of carbon and air pollutants (Dec, 10.1007/s11356-022-24685-z, 2022). Environmental Science and Pollution Research 30: 11357–58. [Google Scholar] [CrossRef]
- Sobaci, Mehmet Zahid, and Kadir Eryigit. 2015. Determinants of E-Democracy Adoption in Turkish Municipalities: An Analysis for Spatial Diffusion Effect. Local Government Studies 41: 445–69. [Google Scholar] [CrossRef]
- Song, Mei, Jin Wu, Mengran Song, Liyan Zhang, and Yaxu Zhu. 2020. Spatiotemporal regularity and spillover effects of carbon emission intensity in China’s Bohai Economic Rim. Science of the Total Environment 740: 140184. [Google Scholar] [CrossRef]
- Soytas, Ugur, Ramazan Sari, and Bradley T. Ewing. 2007. Energy consumption, income, and carbon emissions in the United States. Ecological Economics 62: 482–89. [Google Scholar] [CrossRef]
- Tan, Liu, and Zhang Kaili. 2023. Effects of the digital economy on carbon emissions in China: An analysis based on different innovation paths. Environmental Science and Pollution Research 30: 79451–68. [Google Scholar]
- Tong, Dan, Qiang Zhang, Fei Liu, Guang Geng, Yixuan Zheng, Tao Xue, Chaopeng Hong, Ruili Wu, Yu Qin, and H. Zhao. 2018. Current emissions and future mitigation pathways of coal-fired power plants in China from 2010 to 2030. Environmental Science & Technology 52: 12905–14. [Google Scholar]
- Tsurumi, Tetsuya, and Shunsuke Managi. 2010. Decomposition of the environmental Kuznets curve: Scale, technique, and composition effects. Environmental Economics & Policy Studies 11: 19–36. [Google Scholar]
- Usman, Muhammad, Atif Jahanger, Muhammad Sohail Amjad Makhdum, Daniel Balsalobre-Lorente, and A. Bashir. 2022. How do financial development, energy consumption, natural resources, and globalization affect Arctic countries’ economic growth and environmental quality? An advanced panel data simulation. Energy 241: 122515. [Google Scholar] [CrossRef]
- Valadkhani, Abbas, Russell Smyth, and Jeremy Nguyen. 2019. Effects of primary energy consumption on CO2 emissions under optimal thresholds: Evidence from sixty countries over the last half century. Energy Economics 80: 680–90. [Google Scholar] [CrossRef]
- Visconti-Caparrós, Jose Maria, and Juan Ramon Campos-Blázquez. 2022. The development of alternate payment methods and their impact on customer behavior: The Bizum case in Spain. Technological Forecasting and Social Change 175: 121330. [Google Scholar] [CrossRef]
- Wang, Hui, Xingang Zhao, Lingzhi Ren, Jicheng Fan, and Fan Lu. 2021. The impact of technological progress on energy intensity in China (2005–2016): Evidence from a geographically and temporally weighted regression model. Energy 226: 120362. [Google Scholar]
- Wang, Jianda, Kangyin Dong, Xiucheng Dong, and Farhad Taghizadeh-Hesary. 2022a. Assessing the digital economy and its carbon-mitigation effects: The case of China. Energy Economics 113: 106198. [Google Scholar] [CrossRef]
- Wang, Qiang, Jiayi Sun, Ugur Korkut Pata, Rongrong Li, and Mustafa Tevfik Kartal. 2023. Digital economy and carbon dioxide emissions: Examining the role of threshold variables. Geoscience Frontiers 15: 101644. [Google Scholar] [CrossRef]
- Wang, Xingan, and Min Zhong. 2023. Can digital economy reduce carbon emission intensity? Empirical evidence from China’s smart city pilot policies. Environmental Science and Pollution Research 30: 51749–69. [Google Scholar] [CrossRef]
- Wang, Zhijia, Lijuan Liang, Dong Cheng, Hujun Li, and Yongheng Zhang. 2022b. Emission Reduction Benefits and Economic Benefits of China’s Pilot Policy on Carbon Emission Trading System. Computational Intelligence and Neuroscience 2022: 5280900. [Google Scholar] [CrossRef]
- Wen, Le, Basil Sharp, and Erwann Sbai. 2020. Spatial Effects of Wind Generation and Its Implication for Wind Farm Investment Decisions in New Zealand. The Energy Journal 41: 47–72. [Google Scholar] [CrossRef]
- Wu, Haitao, Yan Xue, Yu Hao, and Siyu Ren. 2021. How does internet development affect energy-saving and emission reduction? Evidence from China. Energy Economics 103: 105577. [Google Scholar] [CrossRef]
- Wu, Xiting, Qun Cao, Xiaoping Tan, and Liang Li. 2020. The effect of audit of outgoing leading officials’ natural resource accountability on environmental governance: Evidence from China. Managerial Auditing Journal 35: 1213–41. [Google Scholar] [CrossRef]
- Xing, Zeyu, Jing Huang, and Jing Wang. 2023. Unleashing the potential: Exploring the nexus between low-carbon digital economy and regional economic-social development in China. Journal of Cleaner Production 413: 137552. [Google Scholar] [CrossRef]
- Xue, Yan, Chang Tang, Haitao Wu, Jiamin Liu, and Yu Hao. 2022. The emerging driving force of energy consumption in China: Does digital economy development matter? Energy Policy 165: 112997. [Google Scholar] [CrossRef]
- Yang, Bo, Minhaj Ali, Shujahat Haider Hashmi, and Atif Jahanger. 2022. Do income inequality and institutional quality affect CO2 emissions in developing economies? Environmental Science and Pollution Research 29: 42720–41. [Google Scholar] [CrossRef]
- Yi, Ming, Yafen Liu, Mingyue Sheng, and Le Wen. 2022. Effects of digital economy on carbon emission reduction: New evidence from China. Energy Policy 171: 113271. [Google Scholar] [CrossRef]
- Zeng, Jingting, and Moru Yang. 2023. Digital technology and carbon emissions: Evidence from China. Journal of Cleaner Production 430: 139765. [Google Scholar] [CrossRef]
- Zhang, Jie, and Fangbin Qian. 2023. Digital economy enables common prosperity: Analysis of mediating and moderating effects based on green finance and environmental pollution. Frontiers in Energy Research 10: 1080230. [Google Scholar] [CrossRef]
- Zhang, Minglong, and Yin Liu. 2022. Influence of digital finance and green technology innovation on China’s carbon emission efficiency: Empirical analysis based on spatial metrology. Science of The Total Environment 838: 156463. [Google Scholar] [CrossRef]
- Zhang, Wei, Xuemeng Liu, Die Wang, and Jianping Zhou. 2022. Digital economy and carbon emission performance: Evidence at China’s city level. Energy Policy 165: 112927. [Google Scholar] [CrossRef]
- Zhang, Weike, Hongxia Fan, and Qiwei Zhao. 2023. Seeing green: How does digital infrastructure affect carbon emission intensity? Energy Economics 127: 107085. [Google Scholar] [CrossRef]
- Zhao, Xiaochun, Laichun Long, and Shi Yin. 2023. Regional common prosperity level and its spatial relationship with carbon emission intensity in China. Scientific Reports 13: 17035. [Google Scholar] [CrossRef]
- Zhou, Xiaoyong, Dequn Zhou, Qunwei Wang, and Bin Su. 2019. How information and communication technology drives carbon emissions: A sector-level analysis for China. Energy Economics 81: 380–92. [Google Scholar] [CrossRef]
- Zhu, Zhichan, Bo Liu, Zhuoxi Yu, and Jianhong Cao. 2022. Effects of the Digital Economy on Carbon Emissions: Evidence from China. International Journal of Environmental Research and Public Health 19: 9450. [Google Scholar] [CrossRef]
Author(s) | Digital Economy Indicators |
---|---|
Chen and Wu (2022) | Computerization, Internet, Digitalization |
Yi et al. (2022) | Digital industrialization, Industry digitization |
Cheng et al. (2023) | Digital infrastructure, Industrial structure, Digital industrial scale, Technological innovation in the digital economy |
Chen et al. (2022) | Mobile phone penetration rate, Internet penetration rate, Related industry output, Related industry employees |
Li et al. (2021a) | Digital infrastructure, Internet development, Digital industry, Digital finance |
Primary Indicators | Secondary Indicators | Description of Indicators (Units) | Index Attribute |
---|---|---|---|
Infrastructure | Broadband Internet infrastructure | Internet users (10,000 households) | + |
Mobile Internet fundamentals | Mobile telephone subscribers (10,000 households) | + | |
Industry development | E-commerce Industry development | Urban e-commerce parks (10,000) | + |
Infrastructure of the information industry | Employees in information transmission, Computer services and software (10,000 persons) | + | |
Telecommunications industry output | Total telecommunication business (100 million) | + | |
Innovation capacity | Digital innovation factor support | Expenditure on science and technology (100 million) | + |
Level of digital Innovation output | Patents related to the digital economy (10,000) | + | |
Digital Hi-Tech penetration | Degree of penetration of digital high-tech applications among listed companies (%) | + | |
Inclusive finance | Digital inclusive finance | Digital financial inclusion coverage breadth index (%) | + |
Depth of use | Depth of use index for digital financial inclusion (%) | + | |
Degree of digitization | Digital financial inclusion digitization index (%) | + | |
Development environment | Talent environment | Number of graduates from general higher education institutions (10,000 persons) | + |
Policy environment | Internal expenditure on R&D personnel costs (100 million) | + |
First Level Index | Second Level Index | Third Level Index | Impact |
---|---|---|---|
Prosperity | Resident life | GDP per capita | + |
Per capita disposable income of rural residents | + | ||
Per capita consumption expenditure of urban residents | + | ||
Per capita consumption expenditure of rural residents | + | ||
Education level | Per pupil education expenditure | + | |
Medical level | Number of hospital beds per capita | + | |
Social service level | Local fiscal general budget expenditure/GDP | + | |
Cultural life level | Public library holdings per capita | + | |
Science and education input | Science and education expenditure/GDP | + | |
Commonality | Urban–rural gap | The ratio of rural residents’ income to urban residents’ income | + |
The ratio of consumption expenditure of rural residents to that of urban residents | + | ||
Regional gap | The ratio of rural residents’ income to the national average rural residents’ income | + | |
The ratio of urban residents’ income to the national average urban residents’ income | + |
Variable | Symbol | Name | Measure |
---|---|---|---|
Dependent variable | CEI | Energy carbon intensity | Carbon emissions per unit of GDP |
Explanatory variable | DIG | Development level of the digital economy | Calculated according to the index system of the digital economy |
Intermediary variable | CP | Development level of the mutual enrichment | Calculated according to the index system of the common wealth |
Control variables | INNOV | Green technology innovation | Number of green patents granted |
IS | Industrial structure | Ratio of tertiary to secondary sector | |
MAR | Marketability | Regional marketization index | |
INUR | R&D intensity | Ratio of R&D expenditure to GDP | |
UR | Urbanization level | Ratio of urban population to total population |
Variable | Obs | Min | Mean | Max | Std. Dev. |
---|---|---|---|---|---|
CEI | 330 | 0.325 | 2.306 | 9.098 | 1.748 |
DIG | 330 | 0.049 | 0.238 | 1.000 | 0.182 |
CP | 330 | 0.187 | 0.763 | 2.245 | 0.436 |
INNOV | 330 | 3.583 | 7.331 | 10.450 | 1.351 |
IS | 330 | 0.518 | 1.218 | 5.296 | 0.695 |
MAR | 330 | 0.526 | 6.804 | 11.910 | 2.056 |
INUR | 330 | 0.004 | 0.016 | 0.011 | 0.064 |
UR | 330 | 0.350 | 0.590 | 0.896 | 0.122 |
(1) CEI | (2) CEI | (3) 2SLS | |
---|---|---|---|
DIG | −2.493 *** (−4.81) | −3.953 *** (−5.26) | −1.655 *** (−2.63) |
INNOV | −0.317 *** (2.72) | −0.449 ** (0.072) | |
MAR | −0.136 ** (−2.93) | 0.039 * (−0.111) | |
IS | 0.108 (0.23) | 0.395 ** (0.365) | |
INUR | 29.835 ** (2.05) | 1.186 ** (0.094) | |
UR | −9.625 *** (−6.51) | −0.395 (0.175) | |
_Cons | 3.246 *** (15.89) | 8.023 *** (2.72) | −14.797 ** (1.632) |
Observations | 330 | 330 | 300 |
Province FE | YES | YES | YES |
Year FE | YES | YES | YES |
Kleibergen-Pa ap rk LM statistics | 89.833 [0.00] | ||
Kleibergen-Pa ap Wald rk F statistics | 56.473 [0.00] | ||
R2 | 0.066 | 0.964 | 0.607 |
(1) | (2) | (3) | (4) | (5) | |
---|---|---|---|---|---|
DIG | −2.493 *** (−4.81) | −3.953 *** (−5.26) | −0.724 ** (−2.88) | −0.811 *** (−5.68) | −7.768 * (−2.86) |
INNOV | −0.317 *** (2.72) | −0.139 *** (3.71) | −0.266 * (−2.05) | −0.253 (−0.45) | |
MAR | −0.136 ** (−2.93) | −0.0398 * (−2.53) | −0.125 ** (−2.70) | −0.183 (−1.93) | |
IS | 0.108 (0.23) | −0.123 * (−2.26) | 0.251 (1.50) | −1.748 ** (−3.25) | |
INUR | 29.835 ** (2.05) | 6.874 (−1.39) | 37.79 * (2.54) | 89.100 (1.59) | |
UR | −9.625 *** (−6.51) | −0.654 (1.10) | −9.495 *** (−5.73) | −21.71 (−1.64) | |
_Cons | 3.246 *** (15.89) | 8.023 *** (2.72) | 9.505 *** (12.64) | 7.803 *** (3.48) | 25.63 (1.67) |
Province FE | YES | YES | YES | YES | YES |
Year FE | YES | YES | YES | YES | YES |
Observations | 330 | 330 | 330 | 330 | 330 |
R2 | 0.006 | 0.964 | 0.977 | 0.965 | 0.993 |
(1) CEI | (2) CEI | (3) CEI | |
---|---|---|---|
DIG | −2.493 *** (−4.81) | −1.817 *** (−5.29) | −1.721 (−1.49) |
CP | 2.553 *** (13.45) | ||
INNOV | −0.118 *** (4.12) | −0.017 (0.18) | |
MAR | −0.0330 *** (−2.89) | −0.052 (−1.41) | |
IS | 0.005 * (1.66) | −0.01 (−1.03) | |
INUR | 15.716 *** (4.42) | −10.284 (−0.88) | |
UR | −3.033 *** (−8.38) | −1.883 (−1.46) | |
_Cons | 3.246 *** (15.89) | 1.743 *** (3.20) | 3.573 ** (2.01) |
Province FE | YES | YES | YES |
Year FE | YES | YES | YES |
Observations | 330 | 330 | 330 |
R2 | 0.066 | 0.967 | 0.978 |
Estimated Coefficient | Standard Error | Z Value | 95% Confidence Interval | ||
---|---|---|---|---|---|
Direct Effect | 0.387 *** | 0.251 | 0.231 | 0.128 | 0.246 |
Indirect Effect | 3.843 *** | 0.214 | 7.811 | 3.423 | 4.264 |
2010 | 2011 | 2012 | 2013 | 2014 | 2015 | 2016 | 2017 | 2018 | 2019 | 2020 | |
---|---|---|---|---|---|---|---|---|---|---|---|
CEI | 0.354 *** (3.266) | 0.352 *** (3.316) | 0.354 *** (3.331) | 0.342 *** (3.241) | 0.340 *** (3.221) | 0.303 ** (2.919) | 0.316 ** (3.003) | 0.353 *** (3.328) | 0.354 *** (3.364) | 0.389 *** (3.674) | 0.316 ** (3.007) |
DIG | 0.110 * (1.381) | 0.220 ** (2.339) | 0.172 ** (1.983) | 0.10 * (1.722) | 0.140 * (1.680) | 0.143 * (1.715) | 0.917 ** (2.176) | 0.197 ** (2.126) | 0.204 ** (2.219) | 0.261 *** (2.727) | 0.269 *** (2.822) |
(1) CEI | (2) Direct Effect | (3) Indirect Effect | (4) Total Effect | |
---|---|---|---|---|
DIG | −3.032 *** (−4.31) | −2.899 *** (−3.60) | −1.170 (−0.50) | −4.069 ** (−1.98) |
_cons | Yes | Yes | Yes | Yes |
Province FE | Yes | Yes | Yes | Yes |
Year FE | Yes | Yes | Yes | Yes |
ρ1 | −1.374 *** (−5.56) | / | / | / |
Sigma2_e | 0.084 *** (12.27) | / | / | / |
R2 | 0.086 | 0.072 | 0.678 | 0.279 |
(1) | (2) | |||||
---|---|---|---|---|---|---|
East | Central | Western | Developed | Medium Developed | Less Developed | |
DIG | −1.710 *** (−3.38) | −6.994 * (−4.68) | −4.951 (−2.14) | −0.913 ** (−3.62) | −1.490 * (−2.27) | −0.845 (−2.25) |
Control variable | Yes | Yes | Yes | Yes | Yes | Yes |
_Cons | 6.759 *** (3.73) | 3.599 (1.41) | 6.69 ** (3.02) | 7.265 *** (4.38) | 0.246 (0.06) | 4.140 (2.18) |
Province FE | YES | YES | YES | YES | YES | YES |
Year FE | YES | YES | YES | YES | YES | YES |
R2 | 0.972 | 0.982 | 0.962 | 0.993 | 0.944 | 0.981 |
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Gao, J.; Zhou, W.; Cheng, J.; Liu, Z. Digital Economy Development, Common Prosperity, and Carbon Emissions: An Empirical Study in China. Economies 2024, 12, 120. https://doi.org/10.3390/economies12050120
Gao J, Zhou W, Cheng J, Liu Z. Digital Economy Development, Common Prosperity, and Carbon Emissions: An Empirical Study in China. Economies. 2024; 12(5):120. https://doi.org/10.3390/economies12050120
Chicago/Turabian StyleGao, Jingke, Wenxiao Zhou, Jinhua Cheng, and Ziyuan Liu. 2024. "Digital Economy Development, Common Prosperity, and Carbon Emissions: An Empirical Study in China" Economies 12, no. 5: 120. https://doi.org/10.3390/economies12050120
APA StyleGao, J., Zhou, W., Cheng, J., & Liu, Z. (2024). Digital Economy Development, Common Prosperity, and Carbon Emissions: An Empirical Study in China. Economies, 12(5), 120. https://doi.org/10.3390/economies12050120