5.1.1 Coal Phaseout and Renewable Energy

I begin with arguably the most significant contributor to PM_2.5 pollution – coal burning. Coal is the most carbon-intensive fossil fuel, and arguably the dirtiest; phasing it out is a crucial step toward achieving emissions reduction and pollution control. Article 1 of the Air Pollution Action Plan lays out policy measures to cut back on the burning of coal for heating and electricity. For instance, the government aims to accelerate central heating, promote coal-to-gas and coal-to-electricity projects, build high-efficiency and energy-conserving coal-fired boilers, and gradually get rid of decentralized coal-fired boilers. Areas where air pollution had been particularly rampant (e.g., Jing-Jin-Ji, Yangtze River delta, Pearl River delta) were slated to finish the construction or renovation of pollution treatment facilities for coal-fired power plants and boilers by the end of 2015. The promotion of clean energy in the residential sector has targeted rural households, which had historically burnt coal in large amounts for winter heating. By the end of 2017, 6 million households – 4.8 million of which were in Jing-Jin-Ji and the surrounding region – switched from the use of coal to natural gas for electricity.

As coal has been undergoing a phaseout, renewable energy has been on the rise. The country is now the world’s leading producer of renewable energy and the leading investor in clean energy research and development (R&D) (Reference Shen, Cain and HuiShen, Cain, and Hui 2019). Policy measures to boost the growth of renewables include massive subsidies, tax cuts, funds for renewable R&D, among others. The amendment to the Renewable Energy Law of the People’s Republic of China (中华人民共和国可再生能源法 [修正本]), which came into effect on April 1, 2010, proposed the launch of a “protective full-amount acquisition system” (Standing Committee of the NPC, 2009). Under this system, state power-grid enterprises are required to purchase the full amount of electricity generated from renewable resources that satisfies the technical standards for grid synchronization. Working toward that goal, the State Council is to work with the state power regulatory authority to determine the proportion of the overall generating capacity to come from renewable resources during a planned period of time. The central government has also been pushing for mandatory integration of renewable energy in electricity generation (Reuters 2016; Shen 2021a).

5.1.2 Clean Production and Industrial Pollution Reduction

Clean production has been a policy goal since the late 1990s. In June 2002, the NPC approved the Clean Production Promotion Law of the People’s Republic of China (中华人民共和国清洁生产促进法), which laid out the foundation of this centrally led endeavor (Standing Committee of the NPC 2002a). Since 2010, more governing documents were issued to promote cleaner production and industrial pollution reduction further. For instance, in April 2010, the MEP issued the Notice to Further Promote Clean Production in Key Industries (关于深入推进重点企业清洁生产的通知), which required annual plans for the assessment and auditing of clean production among key industries such as heavy metal (MEP 2010). In 2012, a presidential decree on the Decision to Revise the Clean Production Promotion Law of the People’s Republic of China (关于修改《中华人民共和国清洁生产促进法》的决定) was promulgated and implemented. It made law the annual planning of clean production and made clean production auditing mandatory for enterprises that pollute beyond national or regional standards, exceed the energy consumption per unit of output standard, or use nocuous or harmful raw materials in the production process (Standing Committee of the NPC 2012).

A series of new policies were targeted at reducing emissions from thermal power plants. In July 2011, the Emission Standard of Air Pollution for Thermal Power Plants (火电厂大气污染物排放标准, aka GB 13223-2011) was revised for the third time, with more stringent emissions limits (MEP and AQSIQ 2011). The limits set for newly built coal-fired power-generating units were 100, 100, and 30 mg/m³ for SO₂, NO_x, and PM emissions, respectively. It was an ambitious policy, especially in comparison with similar policies in the United States (184, 135, and 20 mg/m³ for SO₂, NO_x, and PM, respectively) and the European Union (200, 200, and 30 mg/m³ for SO₂, NO_x, and PM, respectively). In 2014, China introduced ultralow emissions standards for coal-fired power-generating units to limit further their SO₂, NO_x, and PM emissions to 35, 50, and 10 mg/m³, respectively. These ultralow emissions standards covered all existing and future coal-fired power units. Existing units with at least 580 kW installed capacity were required to meet the ultralow emissions standards by 2020. It is estimated that between 2014 and 2017, the annual emissions of SO₂, NO_x, and PM from thermal power plants reduced by 65 percent, 60 percent, and 72 percent, respectively (Reference Tang, Qu, Mi, Bo, Chang, Anadon and WangTang et al. 2019).

Closely related to clean production is the circular economy initiative (循环经济), which seeks to close the loops by turning the outputs from one production process into inputs for another. It emphasizes reducing, reusing, and recycling and was legislated as a national endeavor at the 16th NPC in 2002. An entire chapter of the 11th FYP (2006–10) was devoted to the discussion of the circular economy. The Circular Economy Promotion Law of the People’s Republic of China (中华人民共和国循环经济促进法) was passed by the NPC in 2008 and took effect the following year. The law required local governments to consider circular economy when designing investment and development strategies and enacted targets for the coal, steel, electronics, and chemical and petrochemical industries (Standing Committee of the NPC 2008). More recently, the 12th FYP (2011–15) outlined the national policy shift from resource efficiency to resource recycling, especially for heavy industrial resources, making circular development a national development strategy. The plan proposed a 10-100-1,000 strategy: 10 major programs to recycle industrial waste, convert industrial parks, remanufacture, and develop waste collection and recycling systems; 100 demonstration cities; 1,000 demonstration enterprises or industrial parks. In 2012, the National Development and Reform Commission (NDRC) and the Ministry of Finance called for a complete circular economy transition by 2015 in half of the national industrial parks and 30 percent of the provincial ones, with the goal of achieving close-to-zero pollution discharge in these areas. In January 2013, the State Council promulgated the Circular Economy Development Strategies and Short-Term Action Plan (循环经济发展战略及近期行动计划), a national strategy to achieve a circular economy – and the first of its kind in the world (State Council 2013b). Additional targets for 2015 included increasing energy productivity, measured by GDP per unit of energy by 18.5 percent relative to the 2010 level; improving water productivity by 43 percent; and increasing the output of the recycling industry to RMB 1.8 trillion (about USD 276 billion) from the 2010 level of RMB 1 trillion. Other policy measures included reusing at least 75 percent of coal gangue from mining or 70 percent of pulverized fuel ash from coal combustion during electricity generation. Some of the targets extended into the 13th FYP.

5.1.3 Environmental Impact Assessment of Projects

Environmental impact assessment (EIA) is nothing new in China’s environmental governance, but it was not enforced adequately or taken seriously. The concept of EIA was first introduced in 1973 at the First Conference for National Environmental Protection in Beijing. The first official EIA was conducted in 1979 for a copper mine. In 1981, the State Planning Commission, the State Construction Commission, and the State Economic and Trade Commission jointly issued the Management for Environmental Protection of Capital Construction Projects to provide detailed guidance on how EIAs should be conducted. In 1986, the EIA licensing system was introduced to allow the National Environmental Protection Agency (NEPA) and the EPBs to review assessment standards and revoke licenses if the practitioners, which were mostly research institutes, failed to perform their jobs. However, it was not until around the early 2000s that this system was used with some serious intent (Reference Wang, Morgan and CashmoreWang, Morgan, and Cashmore 2003). After more than two decades of experience with EIA, a revised Environmental Assessment Impact Law of the People’s Republic of China (中华人民共和国环境影响评价法) took effect in 2003. However, it left the then existing project-level EIA system largely intact (Standing Committee of the NPC 2002b).

One prominent reason why EIAs had been implemented poorly is that they were perceived by localities to be impediments to economic progress. The discretion credited to local officials as a result of decentralization reforms, which is documented in detail in Chapter 3, gave room for relaxing the standards of the EIA and approving polluting projects that could contribute to the local economy. Enterprises in receipt of foreign investment and township and village enterprises were, for quite some time, approved without EIAs due to lack of legal provision (Reference Wang, Morgan and CashmoreWang, Morgan, and Cashmore 2003). The situation did not improve much in the 2000s and early 2010s. According to then vice minister of the environment, Pan Yue, in a statement released in February 2016, “Projects unhindered by EIA have become the main cause of pollution, environmental emergencies, chaotic distribution, overcapacity, and disorderly development” (Xinhua 2016).

Actions have been taken in recent years to bring more teeth to the implementation of the EIA Law. As of 2016, an assessment campaign was underway in the Jing-Jin-Ji region, Shanghai, and the Pearl River delta region (Xinhua 2016). In 2016, a newly revised Environmental Assessment Impact Law was passed by the General Assembly of the NPC, which imposes far greater fines for the construction of unapproved or not-yet-approved projects (Standing Committee of the NPC 2016).

5.1.4 Clean Transportation and the Promotion of New Energy Vehicles

Emissions from transportation are one of the three most significant contributors to PM_2.5 pollution. At the heart of the effort to promote clean transportation is the development of NEVs. Supporting the NEV sector is seen by the central government as a critical pathway to realizing four goals: becoming a global leader in the NEV industry, thereby creating jobs and boosting exports; achieving energy security by reducing the country’s oil dependence on the Middle East; reducing urban air pollution from mobile sources; and cutting back on carbon emissions (Reference Howell, Lee and HealHowell, Lee, and Heal 2014). The central government has made aggressive efforts to leapfrog the auto industries of other countries by promoting the domestic NEV industry, including electric vehicles (EVs), hybrid electric vehicles (HEVs), battery electric vehicles, and fuel cell vehicles. In 2012, the State Council announced a target of total sales of five million EVs and HEVs by 2020 (State Council 2012). On May 23, 2014, President Xi declared that developing NEVs is the only way for China to transform from a vast automobile country to a powerful automobile country. In 2015, the State Council promoted the plan of Made in China 2025 (中国制造2025), an initiative to comprehensively upgrade China’s industry; the NEV industry was one of ten key industrial sectors to be promoted (State Council 2015a).

To promote the deployment of NEVs, the Chinese government has enacted numerous policies, such as subsidies and tax benefits. In 2014, the State Council issued instructions on accelerating the deployment of NEVs, which stated that EVs and HEVs would be exempt from vehicle purchase taxes between September 1, 2014, and December 31, 2017, and that subsidies to cities and enterprises would be matched by the scale of NEV deployment (State Council 2014). Later that year, the Notice on Financial Support Policies for the Promotion and Deployment of NEVs during 2016–2020 (关于2016-2020年新能源汽车推广应用财政支持政策的通知), jointly issued by the Ministry of Finance, the Ministry of Science and Technology, the Ministry of Industry and Information Technology, and the NDRC, was circulated for public comment (Ministry of Finance et al. 2014). It includes subsidy information to cities for establishing NEV charging stations.

5.1.5 The Curbing of Overcapacity

Overcapacity in the steel, aluminum, and cement industries, which had been a long-standing problem in China, produced enormous amounts of PM_2.5 pollution without putting the overproduction to good use. According to a European Chamber report, steel production was so untethered from the real market demand that it was more than double the combined production of the next four leading producers – Japan, India, the United States, and Russia. Sixty percent of China’s aluminum production capacity had negative cash flow. In 2011 and 2012 alone, China produced as much cement as the United States did during the entire twenty-first century (European Chamber 2016, 1). The state’s stimulus package in response to the 2007–9 global financial crisis, accompanied by the ease with which producers were able to secure loans from the government, further fostered industrial overcapacity between 2008 and 2014. Such exacerbation was particularly extraordinary in the steel, aluminum, cement, refining, flat glass, and paper industries (European Chamber 2016, 3).

The central government recognized the perils of overcapacity, and a series of policy measures were rolled out to rein it in. To boost demand, the government began promoting urbanization domestically and exports internationally, including through the Belt and Road Initiative. To restrain supply, the government began to impose stricter control on loans and credit as well as higher standards for market entry and project approval; strengthen supervision and enforcement of practices to curb overcapacity; standardize the energy pricing system and curb subsidies in sectors such as aluminum production; accelerate the elimination of industry with backward capacity (European Chamber 2016, 6).

Specifically, as early as August 2009, the State Council revised its policy targets to reduce the negative consequences from overcapacity, such as factory closures, unemployment, and mounting bad loans (State Council 2009). In 2012, the NDRC initiated a progressive electricity pricing system for producers of aluminum. In advance of the 3rd Plenum of the 18th Party Congress in 2013, the State Council put forth water and electricity price reforms, which called for the removal of all local price subsidies and introduced tiered pricing for significant users of water and electricity in sectors defined by overcapacity (State Council 2013c). Existing projects would potentially be reevaluated, and proposed projects would be killed in priority sectors, which included steel, cement, electrolytic aluminum, flat glass, and shipbuilding. These policy initiatives have the potential of reducing PM_2.5 pollution and dampening the political pollution waves.

5.1.6 Strengthened Monitoring and Transparency

Since 2012, a series of new measures and standards have been rolled out to strengthen monitoring and transparency at both the city and the firm levels and to encourage and enable public participation in monitoring environmental performance.

5.2.1 Measuring PM_2.5

PM_2.5 refers to all aerosol particles whose diameter is smaller than 2.5 μm. The most dangerous type of air pollution, PM_2.5 decreases lung function, contributes to cancer, and kills by triggering heart attacks and strokes (Reference Seaton, MacNee, Donaldson and GoddenSeaton et al. 1995; Reference Dominici, Peng, Bell, Pham, McDermott, Zeger and SametDominici et al. 2006). In China, PM_2.5 is mainly generated by the types of economic activities that are most rewarded by cadre evaluation, namely, industrial production, infrastructure projects, and transportation.

For satellite-derived measures, I use annual, ground-level PM_2.5 concentration statistics derived from three NASA satellite sensors and a GEOS-Chem chemical transport model (Reference van Donkelaar, Martin, Brauer and Boysvan Donkelaar et al. 2015; Reference van Donkelaar, Martin, Li and Burnettvan Donkelaar et al. 2019). Unlike SO₂, the small size of PM_2.5 allows it to travel long distances, making it challenging to assign the source prefecture of PM_2.5. In other words, the measured level of concentration may not reflect the level of emissions in that prefecture. For this project, the quantity of immediate interest is the trend in pollutant emission levels. If the level of concentration deviates from the emission level by equal proportions across years, the measured tenure effect’s statistical significance remains intact. I will explain why that is the case with PM_2.5 transport matrices and a box model. More explanation of PM_2.5 pollution measurement can be found in Appendix C. By the time of this writing, satellite-based PM_2.5 concentration levels are available from 2000 to 2017.

For official measures, I refer to local monitor-based monthly PM_2.5 concentration readings. The data are downloaded from www.aqistudy.cn/historydata/. I then aggregate the monthly statistics to the annual level. Some prefectures started measuring and publicizing such readings as early as December 2013, while others did not begin until December 2014, so the yearly figures could span 2014–17 or 2015–17.

5.2.2 Measuring Economic Development

GDP growth rates have been documented to link powerfully to political promotion prospects (Reference BoBo 2002; Reference Li and ZhouChen, Li, and Zhou 2005; Reference Li and ZhouLi and Zhou 2005; Reference Wu, Deng, Huang, Morck and YeungWu et al. 2013). GDP data, covering 2000 to 2017, comes from prefectural statistical yearbooks. Official GDP statistics are believed to be exaggerated. According to the former party secretary of Liaoning Province and the current premier, the volume of rail cargo reflects the state of economic development more objectively. It should be quite accurate because fees are charged based on freight weight (WikiLeaks 2007). Hence cargo volumes are plausibly more reflective of actual economic growth.

In addition, I use satellite-derived nighttime luminosity to proxy the level of economic activity. Nighttime luminosity is a delicate, aggregate measure that captures well the sources of PM_2.5: consumption of electricity generated from the burning of fossil fuels, the nighttime operation of industries, and road lights for nighttime cargo transportation. It has been documented to correlate well with economic activity (Reference Chen and NordhausChen and Nordhaus 2011; Reference Henderson, Storeygard and WeilHenderson, Storeygard, and Weil 2012). Nighttime luminosity data come from the Global Defense Meteorological Satellite Program’s Operational Linescan System (DMSP-OLS) nighttime lights series. Thanks to the high spatial resolution of the luminosity data at 2.7 km x 2.7 km, researchers can create measures for a region as small as a township. These data are available annually from 1992 to 2013.

5.3.1 Before PM_2.5 Control Became Part of Cadre Evaluation

Before PM_2.5 became a criteria air pollutant in prefectures, temporal changes in PM_2.5 suggest that on average, spending one more year in office was associated with a 0.87 μg/m³ increase in annual PM_2.5 concentration (3.90 percent of the standard deviation in PM_2.5 level) – statistically significant at the 0.001 level (Table 5.1). The WHO air quality guideline for PM_2.5 is no more than 10 μg/m³ annually, which means the annual increment is nearly 9 percent of that threshold. Further, confirming theoretical intuition derived from an official emphasis on “steady” and “gradual” implementation, the pattern during a given tenure approximates a linear trend.

Given the diverse sources of PM_2.5, creating an aggregated measure of regulatory stringency in all related sectors is a formidable challenge. It is made even more so due to the often big discrepancies between what is written on paper (e.g., official pollution levy rates) and what happens on the ground (e.g., actual pollution levy applied) in China. However, pollution is generated and mediated via two main pathways: economy and regulation (Reference RingquistRingquist 1993). Is the gradual increase in pollution the result of economic growth and/or regulatory relaxation?

To determine the plausibility of the first pathway, I examine the relationship between economic outputs and pollution. I regress year in office on economic outcomes, measured by official GDP and cargo volume statistics and satellite-derived nighttime luminosity. I find a significant and steady ascension in reported GDP statistics, but opposite trends for cargo volumes and nighttime luminosity. Since the latter two measures are plausibly more objective and reflective of actual economic output, the results suggest that GDP statistics are inflated gradually across time in office to cater to the upper levels’ preference – which is discussed in detail in Chapter 3. These results suggest that the economy may not actually have been booming across leaders’ tenures, which serves to discredit economic growth as a possible mechanism in explaining the political pollution wave. This leaves regulatory forbearance as a more plausible explanation. As such, I assess the (lack of) effects of economic development and environmental regulation on pollution in the last year compared to the previous years using causal mediation analysis in Appendix D; the results suggest that the significantly positive effect of the final year in tenure, compared to all previous years in office, on PM_2.5 level is entirely the result of regulatory relaxation, which is consistent with results from Table 5.2.

Consistent with the qualitative evidence presented earlier in the book, applying laxer regulation could be accomplished as quickly as a phone call (Interview 0715CD03). The lack of inspection by “Tom” could give “Jerry” – a polluting factory – the opportunity to burn cheaper and dirtier coal or not operate their pollution treatment facilities (Reference WangWang 2013).

How might political connection influence the strength of the political pollution wave? Intuitively, having connections could dilute the importance of performance in advancement if there is a substitution effect. In that case, the political pollution wave could be dampened. To quantitatively assess the relationship, I ran regressions using the interaction term between year in office and connection as the explanatory variable on the whole sample and using year in office as the explanatory variable, based on Eq. (5.1), on subsamples of the data. A political connection is conceptualized as being from the same prefecture, having gone to the same college, or having worked at the same work unit at the same time. Details on the criteria and coding procedure for political connection can be found in Appendix A. The results suggest that those without political connections were more incentivized than those who were connected to augment their performance in ways that led to stronger political pollution waves. The results in Table 5.3 suggest that for politically unconnected prefectural party secretaries, each additional year in office was associated with an average of 0.92 μg/m³ increase in PM_2.5 concentration (4.14 percent of the standard deviation in PM_2.5 level) compared to those who were connected.

5.3.2 After PM_2.5 Control Became Part of Cadre Evaluation

After incentives to reduce PM_2.5 were instituted in 2013, how did the patterns in pollution change? On the one hand, the officially monitored and the satellite-derived statistics suggest similar trends in prefectures that were not treated for PM_2.5 reduction: the old political pollution waves continued. As shown in Table 5.4, on average, every additional year the prefectural party secretary spent in office was associated with a 4.72 μg/m³ increase in officially reported PM_2.5 concentration (26.68 percent of the standard deviation in monitor-based PM_2.5 readings). The magnitude is smaller based on satellite-derived PM_2.5 levels, at 1.39 μg/m³ (8.04 percent of the standard deviation in satellite-derived PM_2.5 concentrations).

On the other hand, statistical analysis reveals a tale of two trends for prefectures treated for PM_2.5 reduction. The satellite-based trend suggests that the temporal trend is not statistically different from that for untreated prefectures. However, official monitor-based data reveal a much-dampened political pollution wave – an average of 2.24 μg/m³ increase in PM_2.5 concentration for each additional year spent in the office, which is more than half the magnitude for untreated prefectures. The discrepancy between officially reported and satellite-derived data may suggest that some local leaders had incentives to manipulate official measurements to appear more compliant.

Is the continued political pollution wave the result of gradual regulatory relaxation or economic growth? I find the effect of year in office on reported GDP statistics to be consistent across a given tenure, so official statistics would make economic growth an unlikely mechanism to explain the continued political pollution wave.Footnote ³² As shown in Table 5.5, there is reportedly a gradual scale-up for the industrial regulation of SO₂, but not for dust, which is a source of PM pollution. The lack of a scale-up in economic growth and industrial regulation of dust suggests that regulatory forbearance likely remains the mechanism for the continued political pollution waves.

Similar to trends in the earlier period, prefectural party secretaries without political connections with their direct superiors induced significant political pollution waves, with an annual average increment that could range between 1.81–5.37 μg/m³ (Table 5.6). In prefectures whose party secretaries were not politically connected with their direct superiors, monitor-based statistics suggest that such magnitudes could be 3.49 μg/m³ lower. However, satellite-derived data reveal that the difference between treated and untreated prefectures is insignificant. This may suggest that the unconnected leaders in treated cities were incentivized to manipulate PM_2.5 data to look more compliant with the preference of superiors.

For those who were politically connected, the lack of statistical significance suggests that environmental regulation was consistently applied across a prefectural party secretary’s tenure, regardless of whether the prefecture was treated for a PM_2.5 reduction policy. In other words, the results suggest that politically connected local leaders put up an environmental performance to cater to their superiors’ preferences, which is different from the 2000–10 period. The reversal in the incentives to pander to superiors may suggest that performance and connections were more complementary during 2013–17 than 2000–10.

5.4.1 Bureaucratic Capture

Those who had worked in prefectures where they became party secretaries could be more poised to capture bureaucracies via their superior local knowledge and personal connections. Suppose bureaucratic capture is the dominant mechanism for the political pollution wave. In that case, a testable implication is that individuals who had worked longer in the prefectures before becoming party secretaries would induce stronger political pollution waves.

Placing party secretaries into different bins based on the length of their prior experience working in the prefecture, I find that those with such previous experience and, by extension, a higher capability to capture the environmental bureaucracy are not statistically different from those without prior work experience in the prefecture (Figure 5.1). These results weaken the possibility of bureaucratic capture as the mechanism to explain the political pollution wave.

Figure 5.1 Relationship between having previously worked in the prefecture and the average annual increase in PM_2.5 (original bins: no experience=“0”; 1–3 years’ experience=“1”; 4 or more years’ experience=“2”; alternative bins: no experience=“0”; 1–4 years’ experience=“1”; 5 or more years’ experience=“2”).

Prefectural Yearbooks; www.people.com.cn; www.xinhuanet.com; Reference van Donkelaar, Martin, Brauer and Boysvan Donkelaar et al. 2015; Reference van Donkelaar, Martin, Li and Burnettvan Donkelaar et al. 2019.

5.4.2 Rent-Seeking

Some may argue that an additional, alternative hypothesis is rent-seeking. According to Gordon Tullock, who originated the idea, rent-seeking refers to individuals obtaining benefits for themselves at the cost of someone or something else through the political arena (Reference TullockTullock 1967). Reference KruegerKrueger (1974), Reference PosnerPosner (1975), Reference Buchanan, Buchanan, Tollison and TullockBuchanan (1980), and so on, have further developed the idea. In the case of a political pollution wave, rent-seeking can be understood as local political leaders turning a blind eye to, or even promoting, polluting activities, thus undermining the central government’s environmental goals as well as public health in exchange for personal gains like political promotion.

There are ways for local political leaders to promote social stability and economic development while potentially getting away with the additional pollution. First of all, localities can juke the stats and feed upper levels with misinformation. Sometimes, instead of submitting blatantly doctored data, local environmental authorities and governments may tamper with measurement methodology, such as the number and location of pollution monitors (Interview 03BJ0715). Furthermore, although the public is often encouraged to supervise local compliance, polluting industries and businesses have developed strategies to cope with it. To preempt potential public dissent over air pollution, managers of some enterprises allow operation at night to take advantage of lower electricity costs and to ensure smoke evades the public eye (South China Morning Post 2017). When the sun rises, nocturnal temperature inversion ends, and the warming of the air near the ground will rise, taking the pollutants with it to the upper troposphere.

In China’s context, strategic behavior (e.g., extending regulatory forbearance, misreporting statistics to cater to the preferences of superiors) and rent-seeking are interlinked and inseparable. As discussed in Chapter 3, political rank and wealth are strongly and positively correlated in China. Strategic behavior to gain promotion is often accompanied by rent-seeking. Here I do not and cannot exclude the possibility of rent-seeking, but argue for a career incentive-based theory of pollution regulation.