Abstract
Purpose
Carbon trading mechanism has been adopted to foster the green transformation of the economy on a global scale, but its effectiveness for the power industry remains controversial. Given that energy-related greenhouse gas emissions account for most of all anthropogenic emissions, this paper aims to evaluate the effectiveness of this trading mechanism at the plant level to support relevant decision-making and mechanism design.
Design/methodology/approach
This paper constructs a novel spatiotemporal data set by matching satellite-based high-resolution (1 × 1 km) CO2 and PM2.5 emission data with accurate geolocation of power plants. It then applies a difference-in-differences model to analyse the impact of carbon trading mechanism on emission reduction for the power industry in China from 2007 to 2016.
Findings
Results suggest that the carbon trading mechanism induces 2.7% of CO2 emission reduction and 6.7% of PM2.5 emission reduction in power plants in pilot areas on average. However, the reduction effect is significant only in coal-fired power plants but not in gas-fired power plants. Besides, the reduction effect is significant for power plants operated with different technologies and is more pronounced for those with outdated production technology, indicating the strong potential for green development of backward power plants. The reduction effect is also more intense for power plants without affiliation relationships than those affiliated with particular manufacturers.
Originality/value
This paper identifies the causal relationship between the carbon trading mechanism and emission reduction in the power industry by providing an innovative methodology for identifying plant-level emissions based on high-resolution satellite data, which has been practically absent in previous studies. It serves as a reference for stakeholders involved in detailed policy formulation and execution, including policymakers, power plant managers and green investors.
Keywords
Citation
Han, Y., Tan, S., Zhu, C. and Liu, Y. (2023), "Research on the emission reduction effects of carbon trading mechanism on power industry: plant-level evidence from China", International Journal of Climate Change Strategies and Management, Vol. 15 No. 2, pp. 212-231. https://doi.org/10.1108/IJCCSM-06-2022-0074
Publisher
:Emerald Publishing Limited
Copyright © 2022, Yonghui Han, Shuting Tan, Chaowei Zhu and Yang Liu.
License
Published by Emerald Publishing Limited. This article is published under the Creative Commons Attribution (CC BY 4.0) licence. Anyone may reproduce, distribute, translate and create derivative works of this article (for both commercial and non-commercial purposes), subject to full attribution to the original publication and authors. The full terms of this licence may be seen at http://creativecommons.org/licences/by/4.0/legalcode
1. Introduction
Global climate change has long been a significant threat to sustainable development and thus calls for collective action at the international level to achieve the net-zero emissions target. Although nearly 200 countries have recommitted to Paris Climate Agreement on the COP26, the collective action still finds it easy to fall short of reality due to the classic dilemma of free riding. While neither the cost nor benefit of fulfilling the climate promise is equally distributed across countries, most of them may have incentives to rely on others’ emissions reduction efforts without playing their roles (Nordhaus, 2015). Moreover, in the current complex international environment where the staggering COVID-19 pandemic, Russian–Ukraine conflict and slow transformation of energy structure are intertwined, the supply of clean energy still falls behind a rising demand in energy for boosting economic recovery. Given this circumstance, energy-related carbon emissions that plummeted during the early outbreak of COVID-19 have rebounded ever stronger to an annual record-high level of 36.3 billion tonnes with a yearly growth rate of around 6% in 2021, where coal-fired power plants supplied half of the increase in worldwide electricity demand (International Energy Agency, 2022; Ray et al., 2022). As there is no one-size-for-all solution to environmental damages, it requires more immediate and effective domestic efforts to regulate carbon emissions under a renewed international consensus.
Among all policy tools, market-based climate policy is essential for addressing the dilemma between economic growth and carbon emissions control. The market-based climate policies, in contrast to the command-and-control policies that set strict standards and ignore the costs for compliance with emissions control, provide economic incentives for stakeholders to reduce emissions and allocate resources more efficiently. According to the literature, market-based policies in many forms, such as market-based instruments, environmental taxes and emissions trading, are considered more effective and efficient than command-and-control policies in reducing compliance costs and removing information asymmetry (Pan et al., 2022a). Meanwhile, carbon trading-related policies play a leading role among the diverse options in market-based policies. They ensure that the environmental goal is met, and the tradable allowances allow individual emissions sources to set their own compliance path (Goulder, 2013; Gu et al., 2022). Effectively designed carbon trading programmes provide high environmental certainty, lower administrative costs and increase the accountability of reducing, tracking and reporting emissions (Wang and Chen, 2015). According to World Bank, 65 carbon pricing initiatives cover 47 countries worldwide as of April 2021, most of which are developed countries. For instance, Japan introduced a voluntary emissions trading system in 2005 with coverage over various sectors such as electricity production and distribution. Germany launched the German Combustibles Emissions Trading Act in 2021, extending the sector coverage from mainly the large industrial facilities and power plants set by the European emissions trading system to the heating and transport sectors.
However, the developing countries have been cautious in adopting carbon trading-related policies for the cause of low-carbon transition. On the one hand, the developing countries need a high volume of cost-affordable energy supply during the process of industrialisation in case of falling into the energy insecurity trap. On the other hand, domestic pressures are mounting in the developing countries, as the climate policy may lead to a welfare loss (Gavard et al., 2016). Especially in the fossil-fuel-dependent countries such as China, India and Venezuela, the costs of climate policies may result in potential social instability and economic inequality. Doubtlessly, managing domestic climate challenges is crucial, but the question for the developing countries is how. Considering that most of the developing countries are at different levels of economic status, it is vital to make use of the coordination between government intervention and the market power (Zhou and Wang, 2022). In other words, by combining top-to-down and up-to-top approaches, the developing countries may find their respective ideal pathways towards green development. It is thus essential to conduct in-depth analyses of the emission reduction effects of the carbon trading mechanism.
Nevertheless, the extant literature hardly captures the corporate performance under governmental intervention. Existing studies mainly adopted country/province/city-level evidence to investigate the effectiveness of the carbon trading scheme (for example, Wang et al., 2015; Zhao et al., 2017; Chen et al., 2019) or discussed the impact of the carbon trading scheme on decreasing carbon pollution, technology innovation and related aspects (for example, Clarkson et al., 2015; Pan et al., 2022b; Xiao et al., 2021). Even few studies exclusively examine how the carbon trading mechanism impacts certain firms’ performance in a given sector and, more importantly, whether the corporates’ response brings benefits in alleviating both carbon emissions and air pollution. Hence, it is of great academic and practical importance to identify the effects of the carbon trading mechanism. As one of the largest developing countries and suppliers of Certified Emission Reduction primary market, China has pledged to a goal of reaching the carbon emissions peak by 2030 and carbon neutrality by 2060. To this end, it has made substantial efforts to accelerate decarbonisation represented by implementing the carbon trading pilot mechanism in 2011. It showcases a shift towards market-based policy, emphasising on corporate participation as a supplement to the traditional industrial policy, such as China’s Five-year plans. Additionally, given China’s solid efforts in combating climate challenges may provide references to its developing counterparts on how to deal with carbon emissions reduction by giving a full play to government-market cooperation, it would be crucial to examine whether these attempts are successful as designed.
To bridge the research gap, this study investigates how the market-based environmental regulation influences the coordinated reduction of CO2 and PM2.5 from 2007 to 2016 based on plant-level emissions, taking China’s carbon trading pilot mechanism as a quasi-natural experiment. The empirical results indicate that the carbon trading mechanism induces 2.7% of CO2 emission reduction and 6.7% of PM2.5 emission reduction in power plants in pilot areas on average, implying that the market-based policy encourages the synergy of pollution reduction. However, the reduction effect showcases heterogeneity across corporates. It is statistically significant only in coal-fired power plants but insignificant in their gas-fired counterparts. Furthermore, the reduction effect is significant for power plants operated with different technologies but is more pronounced for those with outdated production technology, indicating the strong potential for green development of power plants with backward technologies. The reduction effect is also more intense for power plants without affiliation relationships than those affiliated with particular manufacturers.
This paper contributes to the existing literature from the following three perspectives. Firstly, we newly constructed a nationwide plant-level emissions panel data set based on high-resolution satellite data from 2007 to 2016, revealing the locations and identities of plant-level emissions in China. Secondly, we apply the difference-in-differences (DID) method to investigate the influence of market-based environmental regulation on dual-track pollution reduction (i.e. CO2 and PM2.5) based on spatially-nuanced plant-level evidence, bridging gaps in earlier research. Finally, we further investigate the heterogeneity of power plant characteristics in terms of fuel, electricity generation technology, ownership structure and affiliation relationship. The heterogeneity analyses provide empirical evidence about enterprise response to and participation in emissions reduction, thus shedding light on the effectiveness of carbon emission trading policy.
The remaining of this paper is arranged as follows. Section 2 briefly reviews the relevant literature. Section 3 presents the research design. Section 4 delves into the empirical results, followed by a further discussion. Section 5 concludes with policy implications.
2. Literature review
The causal relation between carbon trading schemes and carbon emissions reduction has aroused considerable attention in recent years. Extant literature is undertaken mainly from the following two perspectives.
Existing literature delves into the market-based policy for greenhouse gas emissions against the background of climate challenges and further discusses how it accelerates the low-carbon transformation. In fact, the market-oriented mechanism includes diverse forms such as price-based programmes in demand response, cap-and-trade programmes and carbon-trading mechanisms, which would lead to varying environmental outcomes. Wu et al. (2020) showed that market-based environmental regulations significantly improved regional eco-efficiency. Zhou and Wang (2022) found that the carbon emissions trading mechanism was beneficial to green technology innovation, which would be enhanced by environmental legislation and development strategy. In turn, it would improve the performance of carbon emission reduction (Rogge et al., 2011). Given that the market-incentive mechanism pays off mainly by encouraging corporates to participate in carbon emission reduction activities, it induces the companies to adjust their business strategy and strengthen the carbon emissions reduction effect (de Groot et al., 2001; Zhao et al., 2018). Besides, Xie et al. (2022) discussed the impact of the Chinese carbon trading mechanism in a specific sector. They pointed out that the pilot programme led to a structural upgrading in the power generation technology, which would help overcome carbon emission constraints.
Some scholars are inclined to adopt regional emissions data to measure the environmental costs of the carbon trading scheme. It sheds light on how carbon pricing and related policies impact the green transformation. Yang et al. (2021) used Chinese province-year data and found that the environmental outcomes of China’s carbon emissions reduction policy varied across provinces. Fleschutz et al. (2021) indicated that price-based demand response caused an increase in CO2 emissions using European country-specific empirical data. Liu et al. (2021) found that China’s carbon trading programme alleviated the air pollutant emissions level of PM2.5 based on city-level monthly data, extending the existing study of climate policy’s negative impact on greenhouse gas emissions and air pollution.
Although the existing literature has gone to great lengths about the effectiveness of carbon trading mechanisms in reducing greenhouse gas emissions, certain issues still need to be addressed. Firstly, previous literature has limited choices of indicators to measure carbon emissions reduction with a precise concentration on the country/province/city-specific data. Given that carbon emissions could result from a variety of sources other than the firm that owns power plants, using merely macro-level panel data to analyse the impact of the carbon trading mechanism on corporate performance may be insufficient. Secondly, previous studies mainly focus on a particular aspect of the carbon trading mechanism’s environmental consequence or industrial structure optimisation, such as its impact on the carbon emissions reduction, air pollution alleviation and power generation technology structure. Yet most of them fail to consider the co-benefits of reducing both carbon and air pollution emissions, thus neglecting the synergy effect of the carbon trading program. Finally, some scholars are inclined to assess the carbon trading mechanism but pay little attention to a particular sector, especially the power sector, which has long played a significant part in Chinese carbon trading programmes. It thus requires an in-depth study taking the Chinese power sector as a sample.
To bridge these research gaps, this paper provides an innovative and pragmatic methodology for identifying plant-level emissions of CO2 and PM2.5 based on high-resolution (1 × 1 km) satellite data. We then apply the DID method to examine the carbon trading mechanism’s reduction impacts in the power industry and further discuss its heterogeneous effects according to company characteristics.
3. Methodology
3.1 Data and variable definition
3.1.1 Plant-level CO2 and PM2.5 emissions.
The main variables of interest include CO2 and PM2.5 emission, which are obtained by matching two satellite-based high-resolution emission databases, the Open-source Data Inventory for Anthropogenic CO2 (ODIAC) database and the Tracking Air Pollution in China (TAP) database with the geographic location of power plants in China provided by Global Power Plant database developed and maintained by World Resources Institute. The Global Power Plant database collects information about the exact location, power generation capacity, operational status, production technology, fuel and other relevant power plant data from official government data, independent sources and crowdsourced data (World Resources Institute, 2018). This database has proven reliable in the literature, and the detailed information on power plants enables this paper to perform in-depth heterogeneity analyses of power plants’ responses to the carbon trading mechanism (Gotzens et al., 2019; Brinkerink et al., 2021).
CO2 and PM2.5 emission data are, respectively, provided by ODIAC and TAP databases. The ODIAC database integrates data collected from satellite-based night-time light sensors with power plant emission profiles to estimate the spatial extent of fossil fuel CO2 emissions on a global scale (Oda and Maksyutov, 2011; Oda et al., 2018). This fuel-emission-centred estimation strategy also reduces the errors generated by non-anthropogenic emission sources and by emission sources other than fuel consumption, which is out of the scope of this paper (Chen et al., 2020). Meanwhile, the TAP database estimates the PM2.5 emission in China based on a two-stage machine learning model coupled with the decision-tree-based gap-filling method and synthetic minority oversampling technique (Geng et al., 2021; Xiao et al., 2021). Both databases cover the whole geographic area of China at least five years earlier and later than the policy experimentation and have high resolutions of 1 × 1 km. Since all three databases use a unified (World Geodetic System) 84 geographic coordinate system, it is feasible to match the exact geographical locations of power plants with the emission data to obtain plant-level data without significant errors, as shown in Figure 1.
The matching processes are accomplished with QGIS, a free and open-source geographic information system software, and manual data-checking is performed to ensure data accuracy. In all samples, data missing or significant errors occur only in a small portion of the sample (≈ 2%) and should not be problematic after manual data-checking, which verifies the position of locations and cells with ground-level images from the base map provided by Google Earth. Using the best available data from the abovementioned database, we construct a comprehensive CO2 and PM2.5 emission data set that allows for prediction or causal inference related to the emissions of power plants. With updated fuel statistics and satellite data, it is possible to expand the timeframe of the data set. But it is noteworthy that the facility size of the power plant may change dramatically due to construction, termination of operation or many other reasons. Meanwhile, it is possible that more than one high-pollution facilitates operate in the same cell, which may cause the plant-level emissions to be aggregated in the data of the respective cell. It is thus of great importance to evaluate the endogeneity problem and the omitted variable bias when performing analyses on plant-level emission data.
3.1.2 Carbon trading mechanism.
The policy framework of the carbon trading mechanism was first developed in October 2011 according to the “Notice on Carrying out Pilot Carbon Emissions Trading”, which was issued by the National Development and Reform Commission. In the pilot areas, which include Guangdong province, Hubei province, Beijing, Shanghai, Tianjin, Chongqing and Shenzhen, carbon emissions allowances/quotas are allocated to firms according to their respective output, and specific benchmarks apply for some industries, such as power and high-technology industries. Based on the relevant literature, the policy-shock dummy variable is defined as zero for time periods before 2012 and is defined as one for time periods equal to or after 2012 (Wang et al., 2019; Qi et al., 2021; Dong et al., 2022). For the treatment-group dummy variable, the value one is given if the power plants are located in the pilot area; otherwise, the value zero is given.
However, some literature suggests an alternative time-setting method of policy shock since the starting times of the carbon trading markets are different for each pilot area (Zhou et al., 2019; Yu and Li, 2021; Zhang et al., 2022). Shenzhen became the first city to initiate the trading market in June 2013, followed by Shanghai and Beijing in November 2013, then Guangdong, Hubei, Tianjin and Chongqing in June 2014. Therefore, the policy-shock dummy variable is defined as zero for time periods before 2014 and is defined as one for time periods equal to or after 2014 in the robustness test.
3.1.3 Control variables.
The omitted variable bias and endogeneity problem should not be of great concern in this paper because the scope of research is power plants: the policy-making processes are exogenous to the plant-level decision-making, and few variables correlate with both pilot area selection and plant-level CO2 and PM2.5 emissions. However, we add the following control variables by referring to the literature:
electricity generation capacity of power plants;
green finance development level;
ventilation coefficient [1]; and
research input of the area (Li et al., 2017; Jiao et al., 2018; Koçak and Ulucak, 2019; Chen et al., 2020; Lee and Lee, 2022).
3.2 Sample and data source
To reduce the bias generated by unobservable factors, the control group consists of the power plants located in provinces that are geographically surrounding the pilot areas, and the treatment group includes those located in the pilot areas [2]. Meanwhile, it is necessary to exclude emission reduction unrelated to the carbon trading mechanism to minimise the estimation bias. Hence, only samples that strictly match all of the following conditions are included in the estimations:
the power plant is active during the sample time period;
the facility size of the power plant remains at a constant level during the sample period, i.e. no new unit starts productive operation, and no existing unit retires;
no remarkable changes in power output; and
no other high-pollution facilities are located in the same cell, as the plant-level emissions are aggregated in this scenario.
The timeframe of this paper is set as 2007–2016 to increase the number of observations while mitigating the omitted variable bias with strict filtering conditions. After filtering, 110 power plants in 20 provinces/centrally-administered municipalities are included in the sample, in which 21 power plants operate in the pilot area, as shown in Figure 2.
The definitions and data sources are summarised in Table 1, and summary statistics are reported in Table 2. It should be noted that the data set cover power stations with different electricity generation capacity and emission levels. Besides, the research input and green financial development level are much higher in pilot areas than in non-pilot areas, which shows that a selection preference in policy experimentation. In other words, the government tend to choose better-developed areas to conduct the policy experimentation, which may distort the estimation of policy impact if the advantageous market conditions are not controlled. This phenomenon provides the theoretical foundation for the inclusion of control variables in estimations.
The logarithm form is used in estimation for the emissions data of CO2 and PM2.5 as well as the ventilation coefficient since these variables are positively skewed. Table 3 reports the correlations between control variables. The correlation coefficients between some variables are close to 1 and highly statistically significant. To address concerns related to the multicollinearity problem, the variance inflation factor (VIF) test is conducted. The results of VIF are reported in Table 4. Given that the VIF values of all independent variables are less than 5, it can be concluded that the multicollinearity problem is not substantial in this paper.
3.3 Model specification
The following standard DID model is constructed to estimate the causal impacts of the carbon trading mechanism on power plants’ CO2 and PM2.5 emissions. The DID model is a common method for assessing the causal effects of policies or events, and its applications in environmental economics and energy economics are fruitful (Elrod and Malik, 2017; Ghosal et al., 2019; Najjar and Cherniwchan, 2021). The discrepancy between the different areas before initiating the carbon trading mechanism can be mitigated by analysing the difference between the CO2 and PM2.5 emissions of the non-pilot areas and their pilot counterparts both before and after the policy implementation. The baseline model is specified as follows:
4. Results and discussions
4.1 Baseline regression results
The baseline results of estimating the impact of the carbon trading mechanism on Chinese power plants’ emissions are presented in Table 5. The coefficient of the interactive term policy × pilot in column (1) is significantly negative at the 1% level, indicating that the CO2 emissions at the power plant level decreased by 2.2% in the pilot areas after implementing the carbon trading mechanism. This result holds after adding control variables. The coefficient in column (3) is also significantly negative at the 1% statistical level, while the coefficient value changes considerably after adding control variables into the model. The result in column (4) indicates that the PM2.5 emissions of power plants in the pilot areas are reduced by 6.7% due to policy effects. These results imply that the carbon trading policy generates substantial co-benefits of carbon emissions reduction and air pollution control in the power industry. Considering the strong emission intensity of the energy industry in China, such plant-level emission reduction effects are highly considerable.
For control variables, the results generally meet our expectations, and some conclusions can be reached. Intuitively, the electricity generation capacity of a power plant is significantly and positively related to its CO2 and PM2.5 emissions. Meanwhile, green finance development also contributes to the control of CO2 and PM2.5 emissions. Nevertheless, ceteris paribus, increasing regional research input may only decrease the PM2.5 emissions at the power plant level, with little effect on CO2 emissions. In the meanwhile, the ventilation coefficient is not statistically significant.
4.2 Robustness analysis
4.2.1 Parallel trend test.
The parallel trend test is used to visualise the trend between the pilot and non-pilot areas over time to rule out the possibility of non-policy-related factors influencing CO2 and PM2.5 emissions trends. Figure 3 illustrates the trends of CO2 and PM2.5 emissions, respectively. It finds that before the policy implementation, the gap in CO2 emissions between the two areas remains constantly significant, and the gap in PM2.5 emissions is constantly small. The pattern of the two trends changed after the carbon emission programme was implemented in 2011. Thus, it could be concluded that the parallel trend holds for the two variables.
4.2.2 Setting different policy time.
Considering the lagged effects of policy implementation, an alternative policy-shock dummy variable policy2 is used in estimation for additional robustness checks. Table 6 shows that the estimation results with alternative policy time-setting are generally consistent with the baseline results. The coefficients of the DID estimators policy2 × pilot are statistically significant at 1% level, but the value of coefficients decreases on a certain scale, indicating the diminishing marginal utility of the policy effects.
4.2.3 Placebo test.
Since it is impossible to incorporate all applicable regulations related to the emissions of power plants in the estimations, a placebo test is conducted based on randomly assigned “false” pilot areas. According to baseline results, the carbon trading mechanism effectively reduces both CO2 and PM2.5 emissions. Thus, the placebo test includes both variables for all areas. If the policy effects do exist, the coefficient of the mimic interactive term policy2 × pilot is expected to be statistically insignificant (Brewer et al., 2018; Wing et al., 2018).
The DID analysis based on equations (1) and (2) is performed 500 times with randomly assigned 10 areas, and the estimated coefficients and their respective p-values are plotted in Figure 4. As most of the estimated coefficients generated in the placebo test are centred around zero and deviate significantly from the predicted coefficients in baseline regression (−0.022*** and −0.067***), it indicates that the placebo test provides additional evidence that the baseline DID results and conclusions are robust.
4.2.4 Counterfactual test.
To further test the robustness of the results, a counterfactual test is implemented. The periods prior to the introduction of the carbon trading mechanism are selected as the hypothetical year when the mechanism is counterfactually introduced. If under the hypothetical scenarios, the DID estimator is not statistically significant, it can be concluded that no systematic differences between the emissions of the control group and the treatment group exist after removing the impact of the carbon trading mechanism. Therefore, policy2009 × pilot and policy2010 × pilot are introduced into the regression, which indicates the policy implementation years are set to 2009 and 2010. The results of the counterfactual test are reported in Table 7.
The results show that the coefficients of policy2009 × pilot and policy2010 × pilot are not significant for both CO2 and PM2.5 emissions, indicating that before the introduction of the carbon trading mechanism, there does not exist substantial changes in the CO2 and PM2.5 emissions of the power plants in the pilot areas compared to those in non-pilot areas. It thus rules out the possibility that factors which were in play before the introduction of the carbon trading mechanism triggered the result of this paper and further verifying the robustness of the baseline regression findings.
4.3 Heterogeneity analysis
The emission control behaviours differ in power plants with different fuels, electricity generation technologies, ownership structures and affiliate relationships. Further heterogeneity analyses are thus conducted based on the power plant data that is manually collected or provided by the Global Power Plant database.
4.3.1 Fuel and technology heterogeneity.
Intuitively, power plants with different fuels and different electricity generation technologies produce different levels of CO2 and PM2.5 emissions, so as the difficulties in achieving emission reduction. As emission control is gaining acceptance, efficiency improvement, as the prominent practical tool capable of reducing CO2 and PM2.5 emissions from fossil fuel plants in the short-term, has become a key concept for the choice of technology for new plants and upgrades of existing plants.
The sampled power plants can be categorised into two fuel types: coal-powered and gas-powered. As for electricity generation technologies, only the combined cycle technology is available for gas-powered plants, while two different technologies are available for coal-powered plants: subcritical and supercritical. The latter is generally considered the more advanced technology. Subcritical units have power generation efficiencies of between 33% and 37%, whereas efficiency ratings for supercritical coal plants range from 37% to 40%. The increase in efficiency also leads to reductions in emissions given the same level of power output (Gonzalez-Salazar et al., 2018; Rasheed et al., 2021; Whitaker et al., 2012). Empirical evidence shows that the chemical looping combustion-based supercritical and ultra-supercritical units are energetically, exegetically, environmentally and economically advantageous plants for power generation compared to the other variants (Surywanshi et al., 2019). As a result, the impacts of the carbon trading mechanism might be vastly diverse based on the fuel and electricity generation technologies of the power plants. The estimation results of each fuel and electricity generation technology are reported in Table 8.
It finds that the carbon trading mechanism generates significant impacts on coal-power plants, and in particular, coal-power plants with outdated production technology (subcritical). The emission reduction effects are statistically insignificant for coal-powered plants with comparatively more advanced production technology (ultracritical) and for gas-powered plants.
Such a difference can be attributed to two reasons. On the one hand, the less-developed electricity generation technology has more potential for emissions reductions, and thus the policy impact is more significant. On the other hand, the quota calculation model for power plants monolithically applies to all power plants with different production technologies. The quota pressure on technologically disadvantageous power plants is more intense than on technologically advantageous power plants, so as the motivations to improve production processes and to reduce emissions. Therefore, this phenomenon also calls for a more detailed and well-developed quota calculation system that motivates the green transformation of all power plants in the power industry.
4.3.2 Ownership structure heterogeneity.
According to the current literature, the ownership structure of a company may also influence the effectiveness of environmental regulations and policies. State-owned enterprises (SOE) can defy environmental policy with their advantageous political position, i.e. “central protectionism”. The combination of such protectionism and inadequate regulatory capacity in the environmental bureaucracy provides motivations and possibilities for SOEs to violate environmental policies (Eaton and Kostka, 2018; Ran, 2017). Empirical evidence shows that SOEs in the power industry commit over 60% of reported violations (Eaton and Kostka, 2017). It is thus reasonable to further look into the impact of the carbon trading mechanism on power plants owned by SOEs. In China, most power plants are completed owned by SOEs, while a few plants are jointly owned by SOEs and private companies (mixed-ownership) or exclusively owned by private companies (private-ownership). In this paper, both mixed-ownership and private-ownership are considered non-SOE-ownership since their organisational behaviours in emission control are alike (Andersson et al., 2018; Yuan et al., 2021).
As shown in Table 9, the emission reduction effects of the carbon emission trading mechanism are significant for both SOE-owned and non-SOE-owned power plants. While the reductions in CO2 emissions are of the same scale, the PM2.5 emissions reduction is more substantial in SOE-owned power plants than that in non-SOE-owned power plants.
4.3.3 Affiliation relationship heterogeneity.
The affiliation relationship of power plants may also influence the emission reduction impacts of the carbon trading mechanism since the quota can be shared with the parent company for power stations with affiliation. Therefore, the incentives for affiliated plants in emission control are expected to be less substantial compared to non-affiliated plants. The estimation results are reported in Table 10, where one may find that the CO2 and PM2.5 emissions of power plants without affiliation were reduced more than those of power plants with affiliation. This disparity also calls for a more detailed quota calculation system for increasing the emission reduction effects of the carbon trading mechanism.
5. Conclusion and policy implications
Extant research has expressly emphasised the importance of the carbon emissions reduction against the background of global climate change. Carbon trading mechanism has been developed for curbing carbon emissions by highlighting the corporate viability under the market-based regulation on a global scale. This paper delves into the reduction impacts of the carbon trading mechanism in China and its heterogeneity under different corporate characteristics by using Chinese plant-level evidences from 2007 to 2016 in the power industry. We find consistent evidence that the carbon trading mechanism promotes carbon emission reduction, which is in accordance with previous studies. Furthermore, this paper adds to the body of knowledge in these areas by demonstrating that the lowering impacts of carbon trading mechanisms are accompanied by co-benefits such as reduced carbon emissions and air pollution. The findings are resilient to the heterogeneity of corporate when we take the main characteristics of power plants into consideration. Additionally, we find that the reduction effects are more pronounced in the coal-fired power plants with outdated production technologies or in power plants with no affiliation relations with particular manufacturers. It suggests that the carbon trading mechanism should be highly recommended in the developing countries as it pays off by encouraging corporate viability in reducing pollutant emissions.
Our research also leads to policy implications as follows. First, policymakers should attach more importance to the coordination of government policies and market mechanisms so as to accelerate the upgrading of both energy structure and industrial structure in response to the global climate challenge. Second, they may also consider monitoring the reduction effects of the carbon emission reduction-related policy from a micro perspective, especially at the plant level, which would provide more detailed information regarding the actual environmental outcomes. Finally, design and improve the carbon trading mechanism by borrowing relevant experience from other developing countries so as to attract more investors and experts while expanding the types of trading instruments available to increase the carbon market’s efficacy.
Figures
Summary of variable definition and data sources
| Category | Definition | Source | |
|---|---|---|---|
| Dependent variable | co2 | Plant-level CO2 emission data (million tons) | ODIAC database |
| pm25 | Plant-level PM2.5 emission data (μg/m3) | TAP database | |
| Dummy variable | pilot | 1 for the pilot area, 0 for the non-pilot area | – |
| policy | 1 for time periods equal to or after the year 2012, 0 for before 2012 | – | |
| Independent variable | capacity | Installed electricity generation capacity of power plants (MW) | Global Power Plant database |
| greenfin | Green finance development index (1–10) | China Statistical Yearbook, China Insurance Statistical Yearbook, Statistical Yearbooks of Sample Provinces | |
| rd_gdp | R&D expense/GDP (%) | ||
| ven | Ventilation coefficient | Global Environmental Database | |
Summary statistics
| Variable | Obs | Mean | SD | Min | Max |
|---|---|---|---|---|---|
| Panel A: Full sample | |||||
| co2 | 1,100 | 2.702 | 2.705 | 0.132 | 15.590 |
| pm25 | 1,100 | 68.492 | 24.783 | 13.514 | 150.742 |
| capacity | 1,100 | 678.785 | 694.219 | 50.000 | 3,970.000 |
| greenfin | 1,100 | 1.668 | 0.809 | 0.711 | 6.921 |
| rd_gdp | 1,100 | 1.610 | 0.884 | 0.207 | 6.014 |
| ven | 1,100 | 1,233.230 | 283.856 | 632.295 | 2,418.158 |
| Panel B: Pilot area sample | |||||
| co2 | 210 | 2.880 | 3.271 | 0.344 | 15.590 |
| pm25 | 210 | 65.875 | 26.434 | 21.224 | 134.451 |
| capacity | 210 | 774.071 | 930.608 | 150.000 | 3,970.000 |
| greenfin | 210 | 2.469 | 1.091 | 0.852 | 6.921 |
| rd_gdp | 210 | 2.406 | 1.210 | 1.193 | 6.014 |
| ven | 210 | 1,126.406 | 375.880 | 773.027 | 2,418.158 |
| Panel C: Non-pilot area sample | |||||
| co2_origin | 890 | 2.660 | 2.553 | 0.132 | 13.492 |
| pm25_origin | 890 | 69.109 | 24.352 | 13.514 | 150.742 |
| capacity | 890 | 656.301 | 624.125 | 50.000 | 2,560.000 |
| greenfin | 890 | 1.479 | 0.585 | 0.711 | 2.939 |
| rd_gdp | 890 | 1.422 | 0.660 | 0.207 | 2.619 |
| ven | 890 | 1,258.436 | 251.117 | 632.295 | 1,726.304 |
Correlation coefficients of variables
| Variable | capacity | greenfin | ven | rd_gdp |
|---|---|---|---|---|
| capacity | 1 | |||
| greenfin | −0.042 | 1 | ||
| ven | −0.016 | 0.135*** | 1 | |
| rd_gdp | −0.085*** | 0.849*** | 0.174*** | 1 |
***Significant at 1%
Variance inflation factor test
| Variable | VIF | 1/VIF |
|---|---|---|
| capacity | 1.01 | 0.99 |
| greenfin | 3.60 | 0.28 |
| rd_gdp | 3.67 | 0.27 |
| ven | 1.03 | 0.97 |
| Mean VIF | 2.33 | |
Baseline regression results
| Variable | (1) | (2) | (3) | (4) |
|---|---|---|---|---|
| CO2 | CO2 | PM2.5 | PM2.5 | |
| policy × pilot | −0.022*** (−5.799) | −0.022*** (−6.458) | −0.171*** (−4.676) | −0.067*** (−8.284) |
| capacity | 0.021*** (52.317) | 0.006*** (7.792) | ||
| greenfin | −0.004** (−2.368) | −0.034** (−2.559) | ||
| ven | −0.042 (−1.097) | 0.083 (1.106) | ||
| rd_gdp | 0.000 (0.169) | −0.271*** (−6.493) | ||
| _cons | 14.034*** (1.26e + 13) | 4.324*** (8.56e + 13) | ||
| Plant FE | Y | Y | Y | Y |
| Year FE | Y | Y | Y | Y |
| N | 1,100 | 1,100 | 1,100 | 1,100 |
| r2 | 0.974 | 0.974 | 0.737 | 0.797 |
t-values in brackets; models are estimated with Driscoll–Kray errors; **significant at 5%, ***significant at 1%
Robustness check: alternative policy dummy variable
| Variable | (1) | (2) | (3) | (4) |
|---|---|---|---|---|
| CO2 | CO2 | PM2.5 | PM2.5 | |
| policy2 × pilot | −0.016** (−3.094) | −0.013* (−2.005) | −0.157*** (−3.656) | −0.066*** (−4.775) |
| capacity | 0.021*** (47.678) | 0.006*** (6.315) | ||
| greenfin | −0.004** (−2.594) | −0.026* (−1.879) | ||
| ven | −0.028 (−0.652) | 0.120 (1.384) | ||
| rd_gdp | −0.008 (−1.603) | −0.291*** (−8.561) | ||
| _cons | 14.034*** (1.26e + 13) | 4.324*** (8.54e + 13) | ||
| Plant FE | Y | Y | Y | Y |
| Year FE | Y | Y | Y | Y |
| N | 1,100 | 1,100 | 1,100 | 1,100 |
| r2 | 0.974 | 0.974 | 0.723 | 0.797 |
t-values in brackets; models are estimated with Driscoll–Kray errors; *significant at 10%, **significant at 5%, ***significant at 1%
Counterfactual test results
| Variable | (1) | (2) | (3) | (4) |
|---|---|---|---|---|
| CO2 | PM2.5 | CO2 | PM2.5 | |
| policy2009 × pilot | 0.004 (0.583) | −0.053 (−0.665) | ||
| policy2010 × pilot | −0.007 (−1.184) | −0.036 (−1.573) | ||
| capacity | 0.021*** (49.191) | 0.006*** (6.615) | 0.021*** (47.035) | 0.006*** (6.347) |
| greenfin | −0.007*** (−3.544) | −0.044** (−2.618) | −0.007*** (−3.360) | −0.044** (−2.586) |
| ven | −0.023 (−0.558) | 0.119 (1.436) | −0.028 (−0.652) | 0.117 (1.340) |
| rd_gdp | −0.013*** (−3.304) | −0.280*** (−7.069) | −0.007* (−1.881) | −0.284*** (−7.621) |
| Plant FE | Y | Y | Y | Y |
| Year FE | Y | Y | Y | Y |
| N | 1,100 | 1,100 | 1,100 | 1,100 |
| r2 | 0.974 | 0.794 | 0.974 | 0.793 |
t-values in brackets; models are estimated with Driscoll–Kray errors; *significant at 10%, **significant at 5%, ***significant at 1%
Heterogeneity analysis: fuel and electricity generation technology
| Variable | Coal-powered plants | Gas-powered plants | ||||||
|---|---|---|---|---|---|---|---|---|
| Full sample | Subcritical technology | Ultracritical technology | ||||||
| (1) | (2) | (3) | (4) | (5) | (6) | (7) | (8) | |
| CO2 | PM2.5 | CO2 | PM2.5 | CO2 | PM2.5 | CO2 | PM2.5 | |
| policy × pilot | −0.024*** (−6.983) | −0.094*** (−9.840) | −0.022*** (−5.810) | −0.103*** (−7.568) | −0.019 (−1.584) | −0.026 (−0.668) | −0.004 (−0.192) | −0.001 (−0.015) |
| capacity | 0.020*** (50.133) | 0.006*** (8.405) | 0.021*** (53.581) | 0.007*** (9.134) | 0.010*** (29.283) | 0.004*** (5.815) | 0.048*** (56.259) | 0.008** (2.632) |
| greenfin | 0.001 (0.582) | −0.102** (−3.164) | −0.005 (−1.351) | −0.105** (−2.988) | 0.021 (1.666) | −0.186*** (−4.144) | −0.015 (−1.304) | 0.030 (1.220) |
| ven | −0.047 (−1.152) | 0.046 (0.627) | −0.043 (−1.129) | 0.023 (0.334) | −0.100 (−1.260) | −0.280 (−1.586) | −0.013 (−0.373) | 0.326** (2.876) |
| rd_gdp | −0.004 (−1.067) | −0.215*** (−5.561) | −0.002 (−0.524) | −0.206*** (−5.094) | 0.003 (0.235) | 0.088 (0.772) | 0.032 (1.606) | −0.206*** (−3.961) |
| Plant FE | Y | Y | Y | Y | Y | Y | Y | Y |
| Year FE | Y | Y | Y | Y | Y | Y | Y | Y |
| N | 1010 | 1010 | 810 | 810 | 90 | 90 | 90 | 90 |
| r2 | 0.974 | 0.976 | 0.972 | 0.799 | 0.992 | 0.913 | 0.978 | 0.869 |
t-values in brackets; models are estimated with Driscoll–Kray errors; **significant at 5%, ***significant at 1%, power plants with technology marked as “unknown” in database are excluded from technology heterogeneity analysis
Heterogeneity analysis: ownership structure
| Variable | Non-SOE | SOE | ||
|---|---|---|---|---|
| (1) | (2) | (3) | (4) | |
| CO2 | PM2.5 | CO2 | PM2.5 | |
| policy × pilot | −0.022*** (−8.106) | −0.045** (−2.846) | −0.022*** (−4.123) | −0.089*** (−9.155) |
| capacity | 0.035*** (83.932) | 0.008*** (7.429) | 0.018*** (47.770) | 0.005*** (8.266) |
| greenfin | −0.005 (−1.680) | 0.028*** (3.803) | 0.004* (2.069) | −0.116*** (−3.634) |
| ven | −0.021 (−0.960) | 0.239*** (3.996) | −0.047 (−1.084) | 0.064 (0.896) |
| rd_gdp | −0.002 (−0.266) | −0.301*** (−6.666) | 0.001 (0.117) | −0.197*** (−4.966) |
| Plant FE | Y | Y | Y | Y |
| Year FE | Y | Y | Y | Y |
| N | 340 | 340 | 760 | 760 |
| r2 | 0.987 | 0.860 | 0.970 | 0.778 |
t-values in brackets; models are estimated with Driscoll–Kray errors; *significant at 10%, **significant at 5%, ***significant at 1%
Heterogeneity analysis: affiliation relationship
| Variable | Non-affiliated plants | Affiliated plants | ||
|---|---|---|---|---|
| (1) | (2) | (3) | (4) | |
| CO2 | PM2.5 | CO2 | PM2.5 | |
| policy × pilot | −0.024*** (−7.494) | −0.083*** (−6.977) | −0.018* (−2.056) | −0.034** (−2.636) |
| capacity | 0.019*** (67.867) | 0.006*** (9.009) | 0.050*** (20.907) | 0.010*** (3.686) |
| greenfin | −0.002 (−1.151) | −0.027** (−2.283) | −0.009 (−0.863) | −0.048 (−1.373) |
| ven | −0.033 (−1.114) | 0.027 (0.376) | −0.092 (−0.966) | 0.274** (2.513) |
| rd_gdp | −0.004 (−1.217) | −0.257*** (−6.613) | 0.011 (1.203) | −0.310*** (−5.595) |
| Plant FE | Y | Y | Y | Y |
| Year FE | Y | Y | Y | Y |
| N | 890 | 890 | 210 | 210 |
| r2 | 0.978 | 0.789 | 0.966 | 0.854 |
t-values in brackets; models are estimated with Driscoll–Kray errors; *significant at 10%, **significant at 5%, ***significant at 1%
Notes
Ventilation coefficient refers to the product of mixing depth and the average wind speed. It’s an atmospheric state that shows pollution potential or the atmosphere’s capacity to dilute and disseminate pollutants throughout an area (Sujatha et al., 2016; Saha et al., 2019).
The following provinces/centrally-administered-municipalities are defined as pilot areas according to the policy framework: Beijing, Shanghai, Tianjin, Guangdong and Hubei. No available sample is located in Chongqing, and Shenzhen is a part of Guangdong Province. The following provinces surrounding the pilot areas are included in the data set as non-pilot areas: Anhui, Fujian, Guangxi, Guizhou, Hainan, Hebei, Hunan, Jiangsu, Jiangxi, Shaanxi, Shanxi, Sichuan and Zhejiang.
References
Andersson, F.N.G., Opper, S. and Khalid, U. (2018), “Are capitalists green? Firm ownership and provincial CO2 emissions in China”, Energy Policy, Vol. 123, pp. 349-359.
Brewer, M., Crossley, T.F. and Joyce, R. (2018), “Inference with difference-in-differences revisited”, Journal of Econometric Methods, Vol. 7 No. 1, pp. 1-16.
Brinkerink, M., Gallachóir, B.Ó. and Deane, P. (2021), “Building and calibrating a country-level detailed global electricity model based on public data”, Energy Strategy Reviews, Vol. 33, pp. 100592-100512.
Chen, J., Zhao, F., Zeng, N. and Oda, T. (2020), “Comparing a global high-resolution downscaled fossil fuel CO2 emission dataset to local inventory-based estimates over 14 global cities”, Carbon Balance and Management, Vol. 15 No. 1, pp. 1-15.
Chen, Y.E., Fu, Q., Zhao, X., Yuan, X. and Chang, C.-P. (2019), “International sanctions’ impact on energy efficiency in target states”, Economic Modelling, Vol. 82, pp. 21-34.
Clarkson, P.M., Li, Y., Pinnuck, M. and Richardson, G.D. (2015), “The valuation relevance of greenhouse gas emissions under the European Union carbon emissions trading scheme”, European Accounting Review, Vol. 24 No. 3, pp. 551-580.
de Groot, H.L.F., Verhoef, E.T. and Nijkamp, P. (2001), “Energy saving by firms: decision-making, barriers and policies”, Energy Economics, Vol. 23 No. 6, pp. 717-740.
Dong, Z., Xia, C., Fang, K. and Zhang, W. (2022), “Effect of the carbon emissions trading policy on the co-benefits of carbon emissions reduction and air pollution control”, Energy Policy, Vol. 165, p. 112998.
Eaton, S. and Kostka, G. (2017), “Central protectionism in China: the ‘Central SOE problem’ in environmental governance”, The China Quarterly, Vol. 231, pp. 685-704.
Eaton, S. and Kostka, G. (2018), “What makes for good and bad neighbours? An emerging research agenda in the study of Chinese environmental politics”, Environmental Politics, Vol. 27 No. 5, pp. 782-803.
Elrod, A.A. and Malik, A.S. (2017), “The effect of environmental regulation on plant-level product mix: a study of EPA’s cluster rule”, Journal of Environmental Economics and Management, Vol. 83, pp. 164-184.
Fleschutz, M., Bohlayer, M., Braun, M., Henze, G. and Murphy, M.D. (2021), “The effect of price-based demand response on carbon emissions in European electricity markets: the importance of adequate carbon prices”, Applied Energy, Vol. 295, p. 117040.
Gavard, C., Winchester, N. and Paltsev, S. (2016), “Limited trading of emissions permits as a climate cooperation mechanism? US–China and EU–China examples”, Energy Economics, Vol. 58, pp. 95-104.
Geng, G., Xiao, Q., Liu, S., Liu, X., Cheng, J., Zheng, Y., Zhang, Q., Xue, T., Tong, D., Zheng, B., Peng, Y., Huang, X., He, K. and Zhang, Q. (2021), “Tracking air pollution in China: near real-time PM2.5 retrievals from multisource data fusion”, Environmental Science and Technology, Vol. 55 No. 17, pp. 12106-12115.
Ghosal, V., Stephan, A. and Weiss, J.F. (2019), “Decentralized environmental regulations and plant-level productivity”, Business Strategy and the Environment, Vol. 28 No. 6, pp. 998-1011.
Gonzalez-Salazar, M.A., Kirsten, T. and Prchlik, L. (2018), “Review of the operational flexibility and emissions of gas- and coal-fired power plants in a future with growing renewables”, Renewable and Sustainable Energy Reviews, Vol. 82, pp. 1497-1513.
Gotzens, F., Heinrichs, H., Hörsch, J. and Hofmann, F. (2019), “Performing energy modelling exercises in a transparent way - the issue of data quality in power plant databases”, Energy Strategy Reviews, Vol. 23, pp. 1-12.
Goulder, L.H. (2013), “Markets for pollution allowances: what are the (new) lessons?”, Journal of Economic Perspectives, Vol. 27 No. 1, pp. 87-102.
Gu, G., Zheng, H., Tong, L. and Dai, Y. (2022), “Does carbon financial market as an environmental regulation policy tool promote regional energy conservation and emission reduction? Empirical evidence from China”, Energy Policy, Vol. 163, p. 112826.
International Energy Agency (2022), “Global energy review: CO2 emissions in 2021”, IEA, Paris, available at: www.iea.org/reports/global-energy-review-co2-emissions-in-2021-2
Jiao, J., Yang, Y. and Bai, Y. (2018), “The impact of inter-industry R&D technology spillover on carbon emission in China”, Natural Hazards, Vol. 91 No. 3, pp. 913-929.
Koçak, E. and Ulucak, Z.Ş. (2019), “The effect of energy R&D expenditures on CO2 emission reduction: estimation of the STIRPAT model for OECD countries”, Environmental Science and Pollution Research, Vol. 26 No. 14, pp. 14328-14338.
Lee, C.-C. and Lee, C.-C. (2022), “How does green finance affect green total factor productivity? Evidence from China”, Energy Economics, Vol. 107, p. 105863.
Li, X., Chalvatzis, K.J. and Pappas, D. (2017), “China’s electricity emission intensity in 2020 – an analysis at provincial level”, Energy Procedia, Vol. 142, pp. 2779-2785.
Liu, J.-Y., Woodward, R.T. and Zhang, Y.-J. (2021), “Has carbon emissions trading reduced PM2.5 in China?”, Environmental Science and Technology, Vol. 55 No. 10, pp. 6631-6643.
Najjar, N. and Cherniwchan, J. (2021), “Environmental regulations and the cleanup of manufacturing: plant-level evidence”, The Review of Economics and Statistics, Vol. 103 No. 3, pp. 476-491.
Nordhaus, W. (2015), “Climate clubs: overcoming free-riding in international climate policy”, American Economic Review, Vol. 105 No. 4, pp. 1339-1370.
Oda, T. and Maksyutov, S. (2011), “A very high-resolution (1 km×1 km) global fossil fuel CO2 emission inventory derived using a point source database and satellite observations of nighttime lights”, Atmospheric Chemistry and Physics, Vol. 11 No. 2, pp. 543-556.
Oda, T., Maksyutov, S. and Andres, R.J. (2018), “The open-source data inventory for anthropogenic CO2, version 2016 (ODIAC2016): a global monthly fossil fuel CO2 gridded emissions data product for tracer transport simulations and surface flux inversions”, Earth System Science Data, Vol. 10 No. 1, pp. 87-107.
Pan, X., Guo, S., Xu, H., Tian, M., Pan, X. and Chu, J. (2022a), “China’s carbon intensity factor decomposition and carbon emission decoupling analysis”, Energy, Vol. 239, p. 122175.
Pan, X., Pu, C., Yuan, S. and Xu, H. (2022b), “Effect of Chinese pilots carbon emission trading scheme on enterprises’ total factor productivity: the moderating role of government participation and carbon trading market efficiency”, Journal of Environmental Management, Vol. 316, p. 115228.
Qi, S.-Z., Zhou, C.-B., Li, K. and Tang, S.-Y. (2021), “Influence of a pilot carbon trading policy on enterprises’ low-carbon innovation in China”, Climate Policy, Vol. 21 No. 3, pp. 318-336.
Ran, R. (2017), “Understanding blame politics in China’s decentralized system of environmental governance: actors, strategies and context”, The China Quarterly, Vol. 231, pp. 634-661.
Rasheed, R., Javed, H., Rizwan, A., Sharif, F., Yasar, A., Tabinda, A.B., Ahmad, S.R., Wang, Y. and Su, Y. (2021), “Life cycle assessment of a cleaner supercritical coal-fired power plant”, Journal of Cleaner Production, Vol. 279, p. 123869.
Ray, R.L., Singh, V.P., Singh, S.K., Acharya, B.S. and He, Y. (2022), “What is the impact of COVID-19 pandemic on global carbon emissions?”, Science of the Total Environment, Vol. 816, p. 151503.
Rogge, K.S., Schneider, M. and Hoffmann, V.H. (2011), “The innovation impact of the EU emission trading system – findings of company case studies in the German power sector”, Ecological Economics, Vol. 70 No. 3, pp. 513-523.
Saha, D., Soni, K., Mohanan, M.N. and Singh, M. (2019), “Long-term trend of ventilation coefficient over Delhi and its potential impacts on air quality”, Remote Sensing Applications: Society and Environment, Vol. 15, p. 100234.
Sujatha, P., Mahalakshmi, D.V., Ramiz, A., Rao, P.V.N. and Naidu, C.V. (2016), “Ventilation coefficient and boundary layer height impact on urban air quality”, in Wang, Z. (Ed.), Cogent Environmental Science, Vol. 2 No 1 p. 1125284.
Surywanshi, G.D., Pillai, B.B.K., Patnaikuni, V.S., Vooradi, R. and Anne, S.B. (2019), “4-E analyses of chemical looping combustion based subcritical, supercritical and ultra-supercritical coal-fired power plants”, Energy Conversion and Management, Vol. 200, p. 112050.
Wang, Q. and Chen, X. (2015), “Energy policies for managing China’s carbon emission”, Renewable and Sustainable Energy Reviews, Vol. 50, pp. 470-479.
Wang, H., Chen, Z., Wu, X. and Nie, X. (2019), “Can a carbon trading system promote the transformation of a low-carbon economy under the framework of the porter hypothesis? Empirical analysis based on the PSM-DID method”, Energy Policy, Vol. 129, pp. 930-938.
Wang, P., Dai, H., Ren, S., Zhao, D. and Masui, T. (2015), “Achieving Copenhagen target through carbon emission trading: economic impacts assessment in Guangdong province of China”, Energy, Vol. 79, pp. 212-227.
Whitaker, M., Heath, G.A., O’Donoughue, P. and Vorum, M. (2012), “Life cycle greenhouse gas emissions of coal-fired electricity generation”, Journal of Industrial Ecology, Vol. 16, pp. S53-S72.
Wing, C., Simon, K. and Bello-Gomez, R.A. (2018), “Designing difference in difference studies: best practices for public health policy research”, Annual Review of Public Health, Vol. 39 No. 1, pp. 453-469.
World Resources Institute (2018), “Global power plant database”, available at: http://resourcewatch.org/, https://earthengine.google.com/ (accessed 13 May 2022).
Wu, H., Hao, Y. and Ren, S. (2020), “How do environmental regulation and environmental decentralization affect green total factor energy efficiency: evidence from China”, Energy Economics, Vol. 91, p. 104880.
Xiao, J., Li, G., Zhu, B., Xie, L.H.Y. and Huang, J. (2021), “Evaluating the impact of carbon emissions trading scheme on Chinese firms’ total factor productivity”, Journal of Cleaner Production, Vol. 306, p. 127104.
Xiao, Q., Geng, G., Cheng, J., Liang, F.L.R., Meng, X., Xue, T., Huang, X., Kan, H., Zhang, Q. and He, K. (2021), “Evaluation of gap-filling approaches in satellite-based daily PM2.5 prediction models”, Atmospheric Environment, Vol. 244, p. 117921.
Xie, L., Zhou, Z. and Hui, S. (2022), “Does environmental regulation improve the structure of power generation technology? Evidence from China’s pilot policy on the carbon emissions trading market(CETM)”, Technological Forecasting and Social Change, Vol. 176, p. 121428.
Yang, B., Liu, L. and Yin, Y. (2021), “Will China’s low-carbon policy balance emission reduction and economic development? Evidence from two provinces”, International Journal of Climate Change Strategies and Management, Vol. 13 No. 1, pp. 78-94.
Yu, D.-J. and Li, J. (2021), “Evaluating the employment effect of China’s carbon emission trading policy: based on the perspective of spatial spillover”, Journal of Cleaner Production, Vol. 292, p. 126052.
Yuan, R., Li, C., Li, N., Khan, M.A., Sun, X. and Khaliq, N. (2021), “Can mixed-ownership reform drive the green transformation of SOEs?”, Energies, Vol. 14 No. 10, p. 2964.
Zhang, W., Li, G. and Guo, F. (2022), “Does carbon emissions trading promote green technology innovation in China?”, Applied Energy, Vol. 315, p. 119012.
Zhou, F. and Wang, X. (2022), “The carbon emissions trading scheme and green technology innovation in China: a new structural economics perspective”, Economic Analysis and Policy, Vol. 74, pp. 365-381.
Zhao, X., Wu, L. and Li, A. (2017), “Research on the efficiency of carbon trading market in China”, Renewable and Sustainable Energy Reviews, Vol. 79, pp. 1-8.
Zhou, J., Huo, X., Jin, B. and Yu, X. (2019), “The efficiency of carbon trading market in China: evidence from variance ratio tests”, Environmental Science and Pollution Research, Vol. 26 No. 14, pp. 14362-14372.
Zhao, Y., Wang, C., Sun, Y. and Liu, X. (2018), “Factors influencing companies’ willingness to pay for carbon emissions: emission trading schemes in China”, Energy Economics, Vol. 75, pp. 357-367.
Further reading
Liu, L., Chen, C., Zhao, Y. and Zhao, E. (2015), “China’s carbon-emissions trading: overview, challenges and future”, Renewable and Sustainable Energy Reviews, Vol. 49, pp. 254-266.
Acknowledgements
This work was supported by the Major Programme of the National Social Science Foundation of China [Grant No: 21&ZD074]; The National Natural Science Foundation of China [Grant No. 71873041; No. 72073037]; China Postdoctoral Science Foundation[Grant No:2021M700907]; The Natural Science Foundation of Guangdong Province, China [Grant No. 2021A1515011814; No. 2022B1515020008]; Guangdong University Student Innovation Training Project [Grant No. 202111846012; No. S202111846027].
Corresponding author
About the authors
Yonghui Han, PhD, is a Professor of World Economics at Guangdong Institute for International Studies, Guangdong University of Foreign Studies. His research focuses on industrial policy and world economics. He has published more than 90 articles in international authoritative journals such as Energy Policy, International Review of Economics and Finance and Emerging Markets Finance and Trade.
Shuting Tan is a PhD candidate at Guangdong Institute for International Studies, Guangdong University of Foreign Studies, whose research interests include industrial policy, developmental economics and global economic governance.
Chaowei Zhu is a Junior Researcher at Faculty of Business, Economics and Informatics, University of Zurich, whose academic focuses are economic development, international economics and industrial policy.
Yang Liu, (Corresponding Author) PhD, is a Lecturer at Guangdong Institute for International Studies, Guangdong University of Foreign Studies. Her research interests include economic growth, industrial policy and global value chain.