3.1 Data

We use multiple sources of data to conduct comprehensive research on the effect of information disclosure on air pollution. The datasets include satellite-based air pollution data, data on meteorological conditions, data on the economic and social characteristics of cities, and data for mechanism analysis. The datasets cover annual city-level information from 2005 to 2019.Footnote ⁴ After dropping the observations with missing air quality data, city-level economic and social characteristics, and singleton observations, we obtain 3,973 observations.

3.1.3 Data on city-level economic and social characteristics

To better mitigate the effects of potential bias from unobserved city economic and social characteristics, we select the following variables: the average annual per capita gross domestic product (GDP), fiscal expenditure on science, the proportion of industry in GDP, and the fiscal income at the city level. The data come from the China Urban Statistical Yearbook. To prevent possible bias due to the effect of the New Regulation on cities' economic and social development, we also use the interactions between year fixed effects and city characteristics in 2012. The summary statistics are presented in table 1.

Table 1. Summary statistics

Data sources: Chinese City Statistical Yearbook, 2005–2019; MERRA-2 from NASA; Chinese Innovation Research Database (CIRD); China Industrial and Commercial Registration Enterprise Database; Government Work Reports in prefecture-level city, 2005–2019.

3.2 Empirical strategy

In this study, we aim to determine whether information disclosure is effective in improving air quality. From 2013 to 2015, the air quality information disclosure policy was gradually implemented in three steps, which represents a good shock for the purposes of using a difference-in-differences (DID) method. Specifically, as a first difference, the air quality levels of those cities that had implemented the regulation were different from those of cities that had not implemented it. Furthermore, as a second difference, the air quality levels of cities before and after the implementation of the regulation were also different. Specifically, the estimation specification is as follows:

(1)\begin{equation}{P_{ct}} = {\beta _0} + {\beta _1}\textrm{Polic}{\textrm{y}_{ct}} + {\beta _2}X_{ct}^\mathrm{\prime } + W_{ct}^\mathrm{\prime }\varphi + \mathop \sum \limits_k x_{c,2012}^k\ast {\delta _t} + {\lambda _c} + {\delta _t} + {\mu _{ct}},\; \end{equation}

where ${P_{ct}}$ represents the logarithm of the average annual level of PM₁₀ and PM_2.5 for city c in year t. $\textrm{Polic}{\textrm{y}_{ct}}$ is a policy dummy variable for information disclosure reform that equals 1 if city c implements the policy in year t and 0 otherwise. The coefficient ${\beta _1}$ represents the effects of information disclosure on air pollution. We assume that ${\beta _1}$ is negative, which means that after the air pollution information is exposed, air pollution concentrations significantly decrease.

$X_{ct}^\mathrm{\prime }$ represents a set of city-level economic and social characteristics containing per capita GDP, fiscal expenditure on science, fiscal income, and the proportion of industry in GDP for city c in year t. To isolate the potential influence of weather conditions, we control for meteorological factors $W_{ct}^\mathrm{\prime }$, including wind speed, precipitation, air temperature and humidity. Moreover, city-level fixed effects ${\lambda _c}$ control for all time-invariant factors, including geographical environments. Year fixed effects ${\delta _t}$ control for shocks, for example, the interference of national regulations or industrial economic development, to all cities in a certain year. Standard errors are clustered at the prefecture city level.

The effectiveness of the identification strategy is based on whether the implementation date of each city is exogenous. That is, if the New Regulation had never been implemented, then the cities in the treatment and control groups would exhibit the same air pollution trend. Therefore, the greatest threat to the identification strategy is the implementation date not being random. To solve this problem, we allow the trend to change with city characteristics to control for the different annual trends of air pollution in different cities. Specifically, we add an interaction of city baseline characteristics in 2012 and year fixed effects, $x_{c,2012}^k\ast {\delta _t}$.

4.1 Baseline results

Table 2 presents the estimation results based on formula (1). Columns (1)–(3) show the results with PM_2.5 as the dependent variable, and columns (4)–(6) show the results with PM₁₀ as the dependent variable. The baseline estimation results are shown in columns (1) and (4) for PM_2.5 and PM₁₀, respectively. It is shown that air pollution information disclosure systems help mitigate air pollution. City and year fixed effects are controlled in the regression. We further add the interaction of city characteristics in 2012 and year fixed effects.

Table 2. Baseline results

Notes: (1) Table 2 presents the baseline results. PM_2.5 and PM₁₀ separately represent the annual concentration of PM_2.5 and PM₁₀ in logarithm, respectively. In columns (1) and (4) we report the results without controlling for both city characteristics and weather heterogeneities. In columns (2) and (5) we report the results controlling for weather heterogeneities. In columns (3) and (6) we report the results controlling for both city characteristics and weather heterogeneities. City characteristics include average per capital GDP, fiscal expenditure of science, proportion of industry in GDP, and fiscal income. The weather controls include annual average precipitation, annual average surface temperature, annual average surface specific humidity, and annual average surface wind speed. The baseline regressions also control city level fixed effects, year fixed effects, and interaction of city control in 2012 and year fixed effects. (2) Robust standard errors in parentheses are clustered at the city level.

Other columns report the results that allow the flexible function of city and weather controls. In columns (2) and (5), weather conditions are included. In columns (3) and (6), we further add the city characteristics to the estimation. We obtain consistent results, that is, that there are negative and significant effects of information disclosure on air pollution.

Specifically, the results in columns (3) and (6) show that after the implementation of the New Regulation, the annual concentration of PM_2.5 decreased by 2.7 per cent, and the annual concentration of PM₁₀ decreased by 2.5 per cent. This finding indicates the effectiveness of information disclosure in controlling air pollution. Moreover, Zou (Reference Zou2021) studied the effect of an intermittent monitoring system on air pollution. He found that air quality near monitoring stations is significantly worse during days when pollution monitors are scheduled to be off, which shows that information disclosure has effects on air pollution reduction. Our research strengthens the importance of information disclosure in controlling air pollution.

4.2 Robustness checks

4.2.1 Parallel trend test

Formula (1) assumes that there are underlying parallel trends in the dependent variables in both the control and treatment groups. To check this assumption and study the dynamic effects of air pollution information disclosure, we estimate the event study specification based on formula (2) as follows:

(2)\begin{equation}{P_{ct}} = {\beta _0} + \mathop \sum \limits_{k ={-} 5}^4 {\gamma _k} \cdot {D_{c,\; {t_0} + k}} + {\beta _2}X_{ct}^{\prime} + W_{ct}^{\prime}\varphi + \mathop \sum \limits_k x_{c,2012}^k\ast {\delta _t} + {\lambda _c} + {\delta _t} + {\mu _{ct}},\end{equation}

where ${t_0}$ represents the year of the implementation of the New Regulation for city i. ${D_{c,\; {t_0} + k}}$ is a set of dummy variables that represent the city in year k after the implementation of the regulation and the start of information disclosure. The data cover 5 years before and 4 years after the start of information disclosure. We are interested in the coefficient ${\gamma _k}$. The results satisfy the parallel trend assumption if the coefficients are negative and significant when $k \ge \; 0$ and if the coefficients are nonsignificant when $k < 0$.

The results of the parallel check are shown in figure 2. We find that the coefficients of pollutants PM_2.5 and PM₁₀ suddenly drop to negative but nonsignificant in the year in which the regulation was implemented. In the year following the implementation of the regulation, the coefficients became significant, and the effects lasted for several years. The results of the parallel trend checks are consistent with the baseline results.

Figure 2. Parallel trend test: event study.

Notes: The panels in the figure plot the coefficients and associated 95% confidence intervals from estimating the leads and lags of information disclosure policy, separately for pollutants PM_2.5 and PM₁₀. All effects are relative to the one year before the policy went into effect.

4.2.2 Placebo test

Another possible threat to the reliability of the baseline results is time-invariant unobserved characteristics at the city level. Each city has specific characteristics. By controlling for city-level fixed effects in the baseline regression, we try to remove the effect of the time-invariant factors of cities on air pollution, but we are unable to control for changes in these factors over time. Even though we add economic and social characteristics at the city level, it is impossible to include all influential factors. As a result, following Ferrara et al. (Reference Ferrara, Chong and Duryea2012), we use a placebo check to exclude possible bias in the baseline results. From formula (1), we know that $\hat{\alpha }$ can be obtained from formula (3):

(3)\begin{equation}\hat{\beta } = \beta + \gamma \cdot \frac{{\textrm{cov}(\textrm{trea}{\textrm{t}_{ct}},\; {\varepsilon _{ct}}|W)}}{{\textrm{var}(\textrm{trea}{\textrm{t}_{ct}},\; |W)}}.\end{equation}

In formula (3), we include a set of variables containing all controls and fixed effects, with $\gamma$ representing the influence of unobserved factors on air pollution. If $\gamma = 0$, then $\hat{\beta }$ is proven to be unbiased. However, $\gamma = 0$ cannot be proven. To check for unbiasedness, we use a placebo check by replacing the variable of interest with an influential and randomly selected ‘false’ $\textrm{trea}{\textrm{t}_{ct}}$. $\hat{\beta }$ is assumed to be 0. If $\hat{\beta } \ne 0$, then ‘false’ $\textrm{trea}{\textrm{t}_{ct}}$ has an effect on air pollution. The baseline regression omits this influential factor; thus, the results are biased. Specifically, we randomly generate a ‘false’ variable of interest to produce a ‘false’ estimation, ${\hat{\beta }^{\textrm{random}}}$. This process is repeated 1,000 times, producing 1,000 corresponding ${\hat{\beta }^{\textrm{random}}}$ estimations. Figure A2 in the online appendix represents the distribution of ${\hat{\beta }^{\textrm{random}}}$, from which the coefficients of ${\hat{\beta }^{\textrm{random}}}$ for all pollutants are normally distributed. The results are shown in figure A2 and are consistent with the expectation of the placebo check.

4.2.3 Excluding the potential effects of other regulations

Additionally, other environmental regulations were implemented during the period 2005–2019, which may have caused errors in the baseline results. To address this concern, we consider important environmental regulations in this period, namely, low carbon cities from 2010 to 2013 and the PITI. Additionally, by controlling for year fixed effects, we exclude the potential effects of nationwide environmental regulations, such as environmental laws. By adding dummy variables for these policies to the regression, we control for their potential effects. The results are shown in table 3. We find that the coefficient of each pollutant decreases but is still significant and slightly different from that in the baseline results. After excluding the potential effects of other environmental regulations, the results remain robust.

Table 3. Mechanisms

Notes: (1) Table 3 presents the results of mechanism checks. Columns (1) and (2) check the effects of information disclosure on government awareness. The dependent variable in column (1) indicates the number of air pollution-related words in each city's government work report. Columns (3) and (4) check the mechanism of increasing environmental protection investments. The dependent variable in column (3) shows the investments in managing industrial pollution source (IPSM). The dependent variable in column (4) shows the investments in exhaust gas treatment (IEGT). Columns (5) and (6) check the mechanism of increasing green innovation. The dependent variable in column (5) represents the number of granted green patents in logarithm. The dependent variable in column (6) represents the number of granted practical green patents in logarithm. Column (7) checks the effect of the information exposure on the closure of heavily polluting enterprises, which is measured by the number of heavily polluting enterprises being shut down in logarithm. (2) Robust standard errors in parentheses are clustered at the city level.

4.2.4 Heterogeneous treatment effects

Some recent studies suggest that the DID estimates with staggered treatment rollouts may be biased by heterogeneous treatment effects because staggered DID models compare units treated later to already treated units, which may lead to negative weighting (Goodman-Bacon, Reference Goodman-Bacon2021). To address this concern, we apply the estimators developed by Callaway and Sant'Anna (Reference Callaway and Sant'Anna2021) and De Chaisemartin and d'Haultfoeuille (Reference De Chaisemartin and d'Haultfoeuille2020). Table 4 presents the results, which are shown to still be valid. Our estimates are robust to heterogeneous treatment effects.

Table 4. Determinants of city specific estimates

Notes: (1) Table 4 presents the possible influence factors affecting the city specific estimates. Lnpm25 and lnpm10 separately represent the annual concentration of PM_2.5 and PM₁₀ in logarithm. Lngdp2012 represents the GDP in 2012 in logarithm. Other variables separately indicate secretary (mayor)'s age, education level, and whether he/she was local when the New Regulation was implemented. (2) Robust standard errors in parentheses are clustered at the city level.

5.1 Government awareness

Information disclosure may decrease the amount of air pollution through the channel of increasing the degree of government awareness. An important feature of the Chinese economy is the positive role played by local governments at different levels (Li et al., Reference Li, Liu, Weng, Zhou, Aoki and Wu2012). Corporate behavior, especially that of state-owned enterprises, is guided by the local government (Holmstrom, Reference Holmstrom1999). Against the backdrop of the long-term use of economic growth as the main measure of official promotion (Maskin et al., Reference Maskin, Qian and Xu2000), China developed its economy at the cost of a clean environment. However, the Implementation of Ambient Air Quality Standards (GB3095-2012), which is essential in the implementation of the New Regulation, states that strengthening the regulation on air pollution is ‘a necessary requirement to meet public demand and improve the credibility of the government’. Since then, local officials in China have faced unprecedented pressure to reduce air pollution since the effectiveness of pollution control has become an important criterion for their political performance. Therefore, we assume that information disclosure decreases the amount of air pollution by increasing the degree of government awareness. Government work reports are among the most essential official documents for local governments, summarizing their social and economic achievements in the past year and laying out work plans for the coming year. The content of these work reports reflects the work focus of the city government (Chen et al., Reference Chen, Kahn, Liu and Wang2018).

Therefore, we use the number of words related to air pollution in each city's government work report to represent that government's awareness of the need to reduce the amount of ambient pollution. The results are shown in column (1) in table 3. After the implementation of the New Regulation, the number of words related to air pollution in the cities' government work reports significantly increased by 0.675, which verifies our assumption that strengthening government awareness of air pollution is a possible channel through which to decrease the amount of air pollution. This result is consistent with existing research conclusions: many studies have proven that pollution control is connected to cadre promotion in China (Chen et al., Reference Chen, Qin and Wei2016; Wang and Lei, Reference Wang and Lei2020).

5.2 Environmental protection investments

Due to officials' increased attention to pollution caused by information disclosure, the government, society and enterprises are likely to increasingly invest in protecting the environment. We assume this to be the second possible mechanism. The current literature confirms that under stricter environmental regulation, some enterprises directly reduce the amount of pollutants in production, preventing the generation of pollution at the source (Liu et al., Reference Liu, Shadbegian and Zhang2017). Some enterprises install end-of-pipe pollution treatment equipment to reduce the amount of final emissions (Liu et al., Reference Liu, Shadbegian and Zhang2017; Liao, Reference Liao2018; Huang and Lei, Reference Huang and Lei2021).

We check this channel using the variables of investments in controlling pollution both at the source and at the end of the pipe at the city level. We use investments in industrial pollution source management (IPSM) to measure the intensity of pollution prevention. IPSM is not purely government or corporate behavior. The funding sources for IPSM include government budget funds and self-raised funds from enterprises as well as bank loans and foreign investment, indicating that the governance of industrial pollution sources is the responsibility of society as a whole, rather than the obligation of a single entity. Therefore, IPSM can measure the effectiveness of information disclosure in reducing emissions at the source better than can corporate investment in pollution source management. In column (2) in table 3, we present the results of the effect of information disclosure on IPSM, which show that the New Regulation increases IPSM by 7,520 yuan. We also use investment in exhaust gas treatment (IEGT) to measure the effect of information disclosure on final emission reduction. The results, shown in column (3) in table 3, indicate that since the implementation of the New Regulation, the amount of IEGT has increased by 4,990 yuan. Both of the above results show that information disclosure has a significant positive effect on increasing the amount of environmental protection investments at the city level.

5.3 Green innovation

We also assume green innovation to be a possible mechanism through which information disclosure reduces the amount of air pollution. Abundant literature has proven that stricter environmental regulations encourage enterprises to increase their amount of green investments (Gao and Zheng, Reference Gao and Zheng2017; Liao, Reference Liao2018; Fan et al., Reference Fan, Zivin, Kou, Liu and Wang2019). Studies also show that information exposure affects firms' environmental behaviors by increasing the degree of innovation (Liu et al., Reference Liu, Shadbegian and Zhang2017; Blundell et al., Reference Blundell, Gowrisankaran and Langer2020). Most studies utilize green innovation data from listed companies for microscopic research. In this study, we pay more attention to green innovation at the city level.

We use the green innovation level, which is measured by the numbers of granted green patents and granted applied green patents per year in each city. The data come from the Chinese Innovation Research Database. After dropping enterprises in the financial and real estate industries and listed companies that have suffered losses for two consecutive years or whose stocks have been subject to special treatment (ST enterprises), we calculate the numbers of green patents approved and applied green patents approved by each prefecture-level city each year from 2005 to 2019. Columns (5) and (6) in table 3 present the results. Information disclosure is shown to significantly increase the numbers of green patents and applied green patents by 33.4 per cent and 14.9 per cent, respectively.

5.4 Closure of heavily polluting enterprises

From the above analysis, it can be seen that information disclosure encourages society as a whole to make positive efforts toward reducing the amount of environmental pollution. However, the environmental Kuznets curve shows that developing countries are likely to experience economic challenges due to stricter environmental regulations (Barbier, Reference Barbier1997). With lower emission requirements, some enterprises reduce the amount of pollutants through environmental investments and technological innovation, as demonstrated earlier. Enterprises that are unable to reduce the amount of emissions through proactive means can only reduce their levels of production to meet emission standards, or even shut down (Wang et al., Reference Wang, Wu and Zhang2018; Petroni et al., Reference Petroni, Bigliardi and Galati2019; Cui and Moschini, Reference Cui and Moschini2020). Therefore, elimination may also be a mechanism through which information disclosure reduces the amount of air pollution.

Moreover, we measure the closure status of heavily polluting enterprises at the city level. We summarize the number of heavily polluting enterprises that were shut down each year in each city from 2005 to 2019. The enterprise shutdown information comes from the China Industrial and Commercial Registration Enterprise database, which contains the registration and cancellation information of all enterprises beginning in 1978 and accurately records the dates of enterprise shutdowns. After choosing companies belonging to the heavily polluting industries defined by the ‘Guidelines for Information Disclosure of Listed Companies’, we calculate the number of heavily polluting enterprises that are shut down each year in each city. Column (7) in table 3 shows that after the implementation of the New Regulation, the number of heavily polluting enterprises that were shut down increased by 8.2 per cent, which verifies elimination as a possible mechanism.

6.1 City-specific estimates

Following the method of Greenstone et al. (Reference Greenstone, He, Jia and Liu2022) and Zou (Reference Zou2021), we make estimations based on equation (1) for each city to capture the specific effect of information disclosure on the amount of air pollution for the 271 cities separately. Their estimates and corresponding 95 per cent confidence intervals are presented in figure 3. It is shown that 78.97 per cent and 76.75 per cent of the coefficients are negative and significant, respectively, at the 95 per cent confidence interval, which means that the New Regulation alleviated air pollution in the majority of cities. This finding supports our baseline results that information disclosure helps control air pollution. Specifically, the average coefficients are −0.094 and −0.079 for PM_2.5 and PM₁₀, respectively.Footnote ⁹

Figure 3. Magnitudes of information disclosure in Chinese cities.

Notes: The panels in the figure plot the city's specific estimates and their 95% confidence intervals for 271 cities separately for pollutants PM_2.5 and PM₁₀.

We further perform regression to analyze the determinants of the coefficients of city-specific estimates. We regress the coefficients of PM_2.5 and PM₁₀ on the pollution level (separately measured by annual concentrations of PM_2.5 and PM₁₀ in logarithmic form) before the implementation of the New Regulation, including the economic levels and characteristics of leaders, which include age, education level, and whether they are local for both the mayor and secretary. The results are shown in table 4. We find that the initial pollution and economic levels are influential in causing heterogeneous effects among cities, while the leader's personal characteristics have no effects, which shows that high-quality information disclosure better controls the principal-agent problem.Footnote ¹⁰ The above findings strengthen the conclusion that information disclosure decreases the amount of air pollution.

Table 5. Heterogeneity analysis

Notes: (1) Table 5 represents the results of heterogeneity checks based on different amounts of monitoring stations. Columns (1) and (2) present the effect of information disclosure on PM_2.5 and PM₁₀ for cities with more monitoring stations. Columns (3) and (4) present the effect of information disclosure on PM_2.5 and PM₁₀ for cities with fewer monitoring stations. (2) Robust standard errors in parentheses are clustered at the city level.

6.2 Cities with different numbers of monitoring stations

We also perform a heterogeneity check based on the number of monitoring stations for different cities. For cities with few air pollution monitoring stations, it may be difficult to accurately monitor air quality in areas far from the monitoring equipment. We divide the sample into two groups using the median number of monitoring stations for heterogeneity analysis. The median number of monitoring stations established at the beginning of the New Regulation was four. Moreover, we divide cities into two groups. The group with a higher number of monitoring stations includes cities with at least four monitoring stations; the group with a lower number of monitoring stations includes cities with fewer than four monitoring stations. The results are shown in table 5. Both PM_2.5 and PM₁₀ decrease more in cities with higher numbers of monitoring stations, and the difference is significant (p value = 0.000), compared with cities with lower numbers of monitoring stations. By increasing the amount of investment in monitoring equipment, a city is likely to better control air pollution. Although few studies provide direct evidence of the number of monitoring stations impacting the effectiveness of information disclosure for air pollution, there is some implicative evidence. One possible explanation is that the intensity of supervision influences the effectiveness of pollution control. Chakraborti (Reference Chakraborti2016) shows that plants in communities with lower median ages, higher median incomes and lower percentages of the workforce being employed in manufacturing are more responsive to improving water quality. Such individuals have a deeper understanding of pollution's negative influence and pay more attention to the pollution behavior of nearby enterprises, forming a disguised form of supervision. Monitoring frequency is another dimension in measuring the intensity of supervision. For example, Zou (Reference Zou2021) finds that air quality near monitoring stations is significantly worse during days when pollution monitors are scheduled to be off. These studies indirectly verify our conclusions.