Impact of Environmental Regulation on Efficiency of Green Innovation in China
Abstract
:1. Introduction
2. Literature Review
2.1. Review of Green Innovation Efficiency
2.2. Review of Environmental Regulation
2.3. Research on Impact of Environmental Regulation on Green Innovation Efficiency
- (1)
- Scholars who support the “Porter hypothesis” believe that environmental regulation will encourage enterprises to embrace technological innovation, which, in turn, improves the green innovation efficiency of society as a whole. Brunnermeier and Cohen found that for every $1 increase in environmental governance costs, green innovation efficiency would increase by 0.4% on average [26]. Castellacci and Lie found that mandatory environmental regulations had a potent positive effect on green innovation efficiency [27]. Singh et al. found that environmental regulation policies in Japan drove green innovation efficiency for society as a whole [28]. Zhang and Wang found that both environmental regulation policies and government financial support have a positive effect on green innovation efficiency, but that the former has a greater impact [29]. Wang and Zhang (2018) argued that different environmental regulation policies would positively promote green innovation efficiency, and command-control environmental regulation has a more significant promoting effect [30]. Wang and He (2022) believed that environmental regulation could promote green innovation, and green innovation can promote the upgrading of industrial structures [31].
- (2)
- Other scholars argue that environmental regulations are not conducive to green innovation efficiency because strict restrictions on environmental emissions may increase the costs of enterprises. Domazlicky and Weber argued that the benefits of technological change brought about by environmental regulations could not compensate for the increased costs to the enterprises [32]. Sinn proposed the “green paradox”, arguing that environmental regulations increased the expenditure of enterprises on emission reduction and reduced the efficiency of green innovation [33]. Li and Bi believed that environmental regulation is not conducive to the technological progress of enterprises and green innovation [34].
- (3)
- Another view is that the impact of environmental regulation on green innovation efficiency is uncertain. Kneller and Manderson argued that mandatory environmental regulation policies would increase the costs of pollutant reduction and R&D (Research and Development) in the UK while having little impact on the total capital accumulation [35]. Peuckert pointed out that environmental regulation would squeeze expenditure, inhibit technological innovation in the short run, and promote development in the long run [36]. Peng et al. found that formal and informal environmental regulation policies showed a U-shaped and inverted U-shaped relationship with green innovation efficiency, respectively [37]. Luo and Chen found that environmental regulations have a non-linear relationship with green efficiency through the threshold regression model [38]. Gao and Xiao believed that autonomous environmental regulations have a U-shaped impact on improving the green innovation efficiency of industrial enterprises [39].
3. Research Method
3.1. SBM of Super-Efficiency
3.2. Kernel Density Estimation
3.3. System-GMM
3.4. Indicator Selection and Variable Description
3.4.1. Construction of Green Innovation Efficiency System
3.4.2. Measurement of Environmental Regulation Intensity
3.4.3. Variable Description
4. Analysis of Empirical Results
4.1. Measurement and Analysis of Green Innovation Efficiency in China
4.1.1. Evolution of Green Innovation Efficiency
4.1.2. Dynamic Evolution of Green Innovation Efficiency
4.2. Impact of Environmental Regulation on Green Innovation Efficiency
4.2.1. Empirical Analysis of the Impact Effect of Different Environmental Regulations
4.2.2. Regional Model Estimation
5. Conclusions and Recommendations
5.1. Conclusions
- (1)
- The green innovation efficiency in China is showing a rising trend over time and is at a high level overall. However, it varies greatly among different regions in China. The green innovation efficiency in eastern China is higher than the national average, while that in central and western China is lower than the national average.
- (2)
- The impact of command-control environmental regulation on green innovation efficiency follows an inverted N-shaped pattern, with the trend of downward-upward-downward. The market incentive environmental regulation has a U-shaped influence on green innovation efficiency, with a downward-upward trend. The intensity of command-control environmental regulation in most provinces of China is in a range that can effectively promote the improvement of green innovation efficiency. However, the intensity of market incentive environmental regulation in most provinces has not reached the threshold that can effectively promote the improvement of green innovation efficiency.
- (3)
- The impact of environmental regulations on green innovation efficiency also varies across regions. Command-control environmental regulation has an inverted U-shaped impact on green innovation efficiency in eastern China. Additionally, market incentive environmental regulations have a direct positive impact on green innovation efficiency. The impact of market incentive environmental regulations on green innovation efficiency follows a U-shaped pattern in central China. Both types of environmental regulation have a U-shaped effect on green innovation efficiency in western China.
5.2. Recommendations
- (1)
- For environmental regulation to contribute to green innovation efficiency, the government must ensure that the intensity of environmental regulation reaches the threshold for technological innovation. However, command-control environmental regulations should not be so severe that enterprises are pressured to close or move out. Therefore, the government should control the pollution discharge standard so that the pollution discharge fee is close to or even greater than the cost of enterprises to prevent and control pollution. Encourage enterprises to carry out technological innovation, improve the industrial structure and prevent pollution from the source. The market incentive environmental regulation policies in most provinces of China have not worked well. The government should provide better guidance regarding market-incentive environmental regulations and make them work hand in hand with command-control environmental regulations to jointly achieve good policy effects. Additionally, the government can adopt a combination of incentives and mandatory measures to manage enterprises. Enterprises that do a good job in terms of discharging pollutants should be given some incentive subsidies or appropriate tax reductions. For some heavily polluting enterprises, compulsory policies can be adopted. The government should urge them to rectify the situation and force them to optimize their industrial structure. Additionally, the government should better guide enterprises which are seeking to engage in technological innovation and focus on environmental protection.
- (2)
- The contribution of technological innovation to green innovation is significant. As the primary creators in innovation activities, enterprises have the responsibility to promote the innovation of the whole industry. The role of enterprises is crucial. First of all, enterprises should fully understand the government’s environmental regulation policies and implement pollution prevention and control policies. Secondly, enterprises choose the most appropriate way to control pollution according to the needs of their development and based on maximizing their benefits. Enterprises should adjust their industrial structure and use more environmentally friendly raw materials for production. The concept of green production runs through the whole production process, and enterprises try to minimize the pollution from the source. Finally, enterprises should reduce investment in industries that produce more pollutants, develop green industries, and play the role of sustainable incentive for green industries.
- (3)
- Environmental regulation policies in different regions have different impacts on the efficiency of green innovation. The government should improve the environmental regulation policy system and formulate policies according to the development needs and the resource endowment of different regions and the conditions for policy implementation. The previous development strategy can be continued in eastern China to attract talents for technological innovation and promote regional innovation while developing the economy. More incentive policies and measures should be implemented to accelerate green innovation efficiency. The implementation of command-control environmental regulation policies should not be too strict to prevent the emergence of a “pollution paradise”. The intensity of environmental regulation should be increased, and policies should be actively implemented so that the intensity of environmental regulation reaches a threshold in central and western China. The government should force enterprises to meet emission standards through innovation, thereby promoting green innovation and efficiency.
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
Appendix A
Region | Province | 2009 | 2010 | 2011 | 2012 | 2013 | 2014 | 2015 | 2016 | 2017 | 2018 | 2019 |
---|---|---|---|---|---|---|---|---|---|---|---|---|
Eastern | Beijing/BJ | 1.9572 | 1.8197 | 1.8218 | 1.8959 | 1.9637 | 1.9703 | 2.0041 | 1.8847 | 2.151 | 2.2307 | 2.1611 |
Tianjin/TJ | 1.0432 | 1.008 | 1.0156 | 1.115 | 1.1118 | 1.0916 | 1.043 | 1.0827 | 1.0102 | 0.574 | 1.0248 | |
Liaoning/LN | 0.5077 | 1.0265 | 0.5523 | 0.4831 | 0.5506 | 0.4076 | 0.4659 | 0.4505 | 0.4091 | 0.4399 | 0.4404 | |
Shanghai/SH | 0.5847 | 0.4837 | 1.0068 | 0.7096 | 0.6054 | 0.5692 | 0.5518 | 0.595 | 0.603 | 1.0022 | 0.6007 | |
Jiangsu/JS | 1.0617 | 1.0995 | 1.1009 | 1.22 | 1.2307 | 1.0745 | 1.0469 | 1.0983 | 1.1237 | 0.6883 | 0.608 | |
Zhejiang/ZJ | 1.1632 | 1.0811 | 1.0977 | 1.0869 | 1.0618 | 1.0534 | 1.0184 | 1.0993 | 1.0229 | 1.0031 | 0.5523 | |
Fujian/FJ | 0.6163 | 0.4626 | 0.6567 | 1.0642 | 0.701 | 0.5996 | 0.651 | 0.636 | 0.5627 | 0.5023 | 0.5155 | |
Shandong/SD | 1.0479 | 0.5871 | 0.7005 | 0.6813 | 0.6519 | 0.59 | 0.5697 | 0.5338 | 0.5505 | 0.6339 | 0.7032 | |
Guangdong/GD | 0.4596 | 1.4324 | 1.1643 | 1.1879 | 1.3403 | 1.3958 | 1.0932 | 1.1078 | 1.2896 | 1.1453 | 1.148 | |
Hainan/HI | 1.1198 | 1.1249 | 1.1264 | 1.1027 | 1.0944 | 1.0981 | 1.1044 | 1.1002 | 1.0971 | 1.0823 | 1.1544 | |
Hebei/HE | 0.4378 | 0.4232 | 0.3995 | 0.6433 | 0.4287 | 0.4405 | 0.4087 | 0.4184 | 0.4435 | 1.0415 | 1.1192 | |
Central | Shanxi/SX | 1.0017 | 1.0974 | 1.0077 | 0.6922 | 1.0091 | 1.0398 | 1.0821 | 0.3565 | 0.4801 | 1.0197 | 1.0025 |
Neimenggu/NM | 1.0847 | 1.1426 | 1.1865 | 1.1151 | 1.1107 | 1.0925 | 1.0759 | 0.5613 | 1.15 | 1.0586 | 1.0264 | |
Jilin/JL | 0.6162 | 1.0332 | 0.4285 | 0.569 | 1.0155 | 0.6002 | 0.7803 | 0.6009 | 0.4933 | 0.5547 | 0.756 | |
Heilongjiang/HL | 0.1885 | 0.1397 | 0.2617 | 0.4167 | 0.2475 | 0.2729 | 0.2434 | 0.3059 | 0.2439 | 0.4226 | 0.6098 | |
Anhui/AH | 1.0859 | 1.0897 | 1.0444 | 1.1056 | 1.1103 | 1.0775 | 1.0504 | 1.055 | 1.0403 | 1.0271 | 0.6167 | |
Jiangxi/JX | 0.4168 | 0.4401 | 0.5707 | 1.0217 | 1.0151 | 0.7156 | 0.5694 | 1.0113 | 0.6394 | 0.5451 | 1.0252 | |
Henan/HA | 0.7061 | 0.8123 | 1.0163 | 1.0445 | 1.239 | 1.2112 | 1.226 | 1.1861 | 1.1764 | 1.2795 | 1.1949 | |
Hubei/HB | 0.5823 | 0.5631 | 0.5178 | 0.5573 | 0.5369 | 0.6268 | 0.6499 | 0.6433 | 0.681 | 0.6611 | 0.576 | |
Hunan/HN | 0.6415 | 0.8124 | 0.7734 | 1.0348 | 1.0281 | 0.7775 | 0.6548 | 0.7115 | 0.5935 | 0.5653 | 0.6473 | |
Guangxi/GX | 1.0241 | 1.0362 | 1.0101 | 1.0437 | 1.1224 | 1.1462 | 1.1995 | 1.2687 | 1.2829 | 1.2648 | 1.4608 | |
Western | Chongqin/CQ | 1.06 | 1.0481 | 1.3738 | 1.0802 | 1.0465 | 1.135 | 1.1728 | 1.0117 | 1.052 | 0.6824 | 0.6914 |
Sichuan/SC | 0.5509 | 0.3274 | 1.075 | 0.7411 | 0.7185 | 0.7345 | 0.7533 | 0.6367 | 0.6462 | 0.6376 | 0.5428 | |
Guizhou/GZ | 1.0632 | 0.2046 | 0.2731 | 0.3017 | 0.2446 | 0.2774 | 0.3156 | 1.0167 | 1.028 | 1.0386 | 1.0411 | |
Yunnan/YN | 1.108 | 1.0577 | 1.0106 | 0.7998 | 1.006 | 1.0201 | 0.6446 | 1.0406 | 1.0604 | 1.0505 | 1.049 | |
Shaanxi/SN | 0.296 | 0.4182 | 0.4339 | 0.4051 | 0.3303 | 0.4254 | 0.3213 | 0.3975 | 0.403 | 0.3707 | 0.4159 | |
Gansu/GS | 0.4665 | 0.4478 | 0.6368 | 0.7601 | 0.6596 | 0.6091 | 0.718 | 0.589 | 0.557 | 0.543 | 1.0143 | |
Qinghai/QH | 0.2332 | 1.0174 | 1.3932 | 1.0073 | 0.1332 | 1.0246 | 1.0395 | 1.0925 | 1.005 | 1.0188 | 1.0104 | |
Ningxia/NX | 0.465 | 0.3801 | 0.4091 | 0.4048 | 0.4001 | 0.379 | 0.3727 | 0.3537 | 0.2703 | 0.4079 | 1.0145 | |
Xinjiang/XJ | 1.4049 | 1.1558 | 1.0418 | 1.5436 | 1.4918 | 1.4577 | 1.1934 | 1.3076 | 1.064 | 1.1919 | 1.2816 |
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Coefficient Value | Shape of Regression Curve | Indication |
---|---|---|
Monotonically increasing or decreasing | The intensity of environmental regulation promotes or inhibits green innovation efficiency. | |
U-shaped | The green innovation efficiency first decreases and then increases with the increase of the intensity of environmental regulation. | |
Inverted U-shaped | The green innovation efficiency first increases and then decreases with the increase of the intensity of environmental regulation. | |
, | N-shaped | The green innovation efficiency first increases, decreases to a certain level, and finally increases again with the increase of the intensity of environmental regulation. |
, | Inverted N-shaped | The green innovation efficiency first decreases, increases to a certain level, and finally decreases again with the increase of the intensity of environmental regulation. |
Type | Indicator | Definition | Source |
---|---|---|---|
Input | Green input | Energy consumption (ten thousand tons of standard coal) | China Energy Statistical Yearbook |
Innovation input | Full-time equivalent of R&D personnel (ten thousand man-years) | China Statistical Yearbook on Science and Technology | |
Internal expenditure of R&D funds (ten thousand yuan) | China Statistical Yearbook on Science and Technology | ||
Output | Innovation desirable output | New product sales revenue (ten thousand yuan) | China Statistical Yearbook on Science and Technology |
Regional GDP (billion yuan) | China Statistical Yearbook | ||
Number of domestic patent applications accepted (piece) | China Statistical Yearbook on Science and Technology | ||
Green undesirable output | Total industrial sulfur dioxide emissions (ton) | China Statistics Yearbook on Environment | |
Organic matter content in industrial wastewater (ton) | China Statistics Yearbook on Environment |
Type | Variable Name | Definition |
---|---|---|
Explained variable | Green innovation efficiency ) | Efficiency measured by the SBM of super-efficiency |
Explanatory variable | Environmental Regulation Intensity ) | Intensity of command-control environmental regulation and market incentive environmental regulation |
Control variable | Government support | Proportion of local fiscal expenditure in regional GDP |
Urbanization | Urbanization rate | |
Technical progress | Turnover of technology market | |
Openness | Ratio of total import and export trade to GDP | |
Human capital | Full-time equivalent of R&D personnel | |
Foreign direct investment | Total amount of foreign investment actually used | |
Optimization of industrial structure | Proportion of tertiary industry value in regional GDP |
Variable | Dynamic Panel System GMM Model | |
---|---|---|
(1) Command-Control Environmental Regulation | (2) Market Incentive Environmental Regulation | |
0.3888 *** | 0.3239 *** | |
(7.22) | (5.93) | |
−1.0215 ** | −0.2415 *** | |
(−2.33) | (−3.56) | |
1.3781 ** | 0.0969 ** | |
(2.3) | (2.48) | |
−0.4908 ** | - | |
(−2.2) | - | |
1.6306 * | 2.5172 ** | |
(1.89) | (2.42) | |
1.2206 *** | 0.7418 *** | |
(4.92) | (2.92) | |
0.1426 *** | 0.1067 *** | |
(3.3) | (−2.72) | |
0.1292 *** | 0.1143 *** | |
(3.59) | (2.76) | |
−0.1953 *** | −0.1955 *** | |
(−14.06) | (−10.41) | |
0.025 | 0.0538 ** | |
(1.39) | (2.41) | |
0.5402 * | 0.4316 * | |
(1.68) | (1.67) | |
−0.8971 | −0.2862 | |
(−1.39) | (−0.6) | |
Curve type | Inverted N-shaped | U-shaped |
Inflection point | 0.5071 1.3677 | 1.2461 |
AR(1) | −3.8475 | −4.0413 |
p-value | 0.0001 | 0.0001 |
AR(2) | −1.7165 | −1.7925 |
p-value | 0.0861 | 0.0731 |
Sargan | 24.4225 | 24.8043 |
p-value | 0.4951 | 0.4734 |
Variable | Dynamic Panel System GMM Model | ||
---|---|---|---|
Eastern | Central | Western | |
0.2102 *** | - | −0.1654 *** | |
(7.64) | - | (14.9) | |
−0.0964 *** | - | 0.0922 *** | |
(3.87) | - | (8.07) | |
Curve type | Inverted U-shaped | - | U-shaped |
Inflection point | 1.619 | - | 0.8970 |
1.8050 *** | −0.1112 ** | −0.1043 *** | |
(7.22) | (−2.16) | (−3.76) | |
- | 0.0735 *** | 0.063 *** | |
- | (7.56) | (8.32) | |
Curve type | Straight line | U-shaped | U-shaped |
Inflection point | - | 0.7565 | 0.6020 |
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Shen, T.; Li, D.; Jin, Y.; Li, J. Impact of Environmental Regulation on Efficiency of Green Innovation in China. Atmosphere 2022, 13, 767. https://doi.org/10.3390/atmos13050767
Shen T, Li D, Jin Y, Li J. Impact of Environmental Regulation on Efficiency of Green Innovation in China. Atmosphere. 2022; 13(5):767. https://doi.org/10.3390/atmos13050767
Chicago/Turabian StyleShen, Tongtong, Dongju Li, Yuanyuan Jin, and Jie Li. 2022. "Impact of Environmental Regulation on Efficiency of Green Innovation in China" Atmosphere 13, no. 5: 767. https://doi.org/10.3390/atmos13050767
APA StyleShen, T., Li, D., Jin, Y., & Li, J. (2022). Impact of Environmental Regulation on Efficiency of Green Innovation in China. Atmosphere, 13(5), 767. https://doi.org/10.3390/atmos13050767