3.3.1 Health effects associated with coal-to-gas for power plant

This part of the estimation is to first link Chinese population exposure with emissions from certain sources (i.e., in this study a power plant unit in Beijing) and then link this with concentration-response (C-R) coefficients from epidemiological evidence. As summarized by Levy, Baxter and Schwartz (Reference Levy, Baxter and Schwartz2009), the effects for health endpoint $k$ from pollutant $j$ from a certain source, $E_{jk}$ , can be calculated by:

(1) $$\begin{eqnarray}E_{jk}=\mathop{\sum }_{i}Pop_{i}\cdot \unicode[STIX]{x1D6E5}C_{ij}\cdot \unicode[STIX]{x1D6FD}_{jk}\cdot I_{k},\end{eqnarray}$$

where $Pop_{i}$ is the population size within cell $i$ , and $\unicode[STIX]{x1D6E5}C_{ij}$ is the contribution of the power plant emission to pollutant $j$ ’s concentration in cell $i$ ( $\unicode[STIX]{x03BC}\text{g}/\text{m}^{3}$ ). The concentration-response (C-R) coefficient with respect to pollution $j$ and health endpoint $k$ is given by $\unicode[STIX]{x1D6FD}_{jk}$ , and $I_{k}$ is the number of new cases of health endpoint $k$ in the population at risk in a given time period.

To estimate $\sum _{i}Pop_{i}\cdot \unicode[STIX]{x1D6E5}C_{ij}$ , models such as CALPUFFFootnote ⁸ focusing on individual power plants (Zhou, Levy, Hammitt & Evans, Reference Zhou, Levy, Hammitt and Evans2003; Zhou, Levy, Evans & Hammitt, Reference Zhou, Levy, Evans and Hammitt2006), or Community Multi-scale Air Quality Model (CMAQ) focusing on a sector level (Zhou, Fu, Zhuang & Levy, Reference Zhou, Fu, Zhuang and Levy2010; Xu, Wang & Zhang, Reference Xu, Wang and Zhang2013) can be applied. In this study, we estimate on a single power plant unit. Instead of performing new CALPUFF modeling, we follow Cropper et al. (Reference Cropper, Gamkhar, Malik, Limonov and Partridge2012) to use an intake fraction (iF) approach. The fraction of emitted pollutant $m$ (either identical to pollutant $j$ or $j$ ’s precursor) from a certain source that is eventually inhaled by the population, $iF_{j,m}$ , is defined as (Bennett et al., Reference Bennett, McKone, Evans, Nazaroff, Margni, Jolliet and Smith2002; Levy et al., Reference Levy, Baxter and Schwartz2009),

(2) $$\begin{eqnarray}iF_{j,m}=\mathop{\sum }_{i}Pop_{i}\cdot \unicode[STIX]{x1D6E5}C_{ij}\cdot BR/Q_{m},\end{eqnarray}$$

where $Q_{m}$ ( $\unicode[STIX]{x03BC}$ g $/$ day) is the emissions of pollutant m from the source, and BR is the breathing rate (20 m $^{3}/$ day-person). In CALPUFF or CMAQ modeling studies, $iF_{j,m}$ is one of the key modeling results that can be used for the estimation of health impacts. Our study is such an application that the $\sum _{i}Pop_{i}\cdot \unicode[STIX]{x1D6E5}C_{ij}$ can be calculated with BR, $iF_{j,m}$ and emission $Q_{m}$ . Therefore Equation (1) becomes,

(3) $$\begin{eqnarray}E_{jk}={iF_{j,m}\cdot Q}_{m}\cdot {\unicode[STIX]{x1D6FD}_{jk}\cdot I}_{k}/BR.\end{eqnarray}$$

We next clarify the choice of parameter values. We use $iF_{\text{p},\text{primary}\,\text{PM}_{2.5}}$ , $iF_{\text{as},\text{SO}_{2}}$ , and $iF_{\text{an},\text{NO}_{\text{x}}}$ (the impact of primary PM $_{2.5}$ , SO $_{2}$ and NO $_{\text{x}}$ emissions on ambient concentration of PM $_{2.5}$ , secondary ammonium sulfate and secondary ammonium nitrate,Footnote ⁹ respectively) estimated in Zhou et al. (Reference Zhou, Levy, Hammitt and Evans2003). The authors estimated the impact of an 800MW coal fired power plant in Beijing on ambient air quality with CALPUFF modeling domain covering most of China. Compared to other $iF_{j,m}$ estimates in China (Wang et al., Reference Wang, Hao, Ho, Li and Lu2006; Hao et al., Reference Hao, Wang, Shen, Li and Hu2007; Zhou et al., Reference Zhou, Fu, Zhuang and Levy2010, Reference Zhou, Hammitt, Fu, Gao, Liu and Levy2014), these $iF_{j,m}$ match best our objective, since they represent the aggregated national air quality impacts of one power plant located exactly in Beijing.Footnote ¹⁰ For $Q_{m}$ , we apply the average emission of SO $_{2}$ , NO $_{\text{x}}$ and PM $_{2.5}$ per Beijing power plant unit (Luo, Reference Luo2012). Once a unit becomes a gas fired one, PM $_{2.5}$ and SO $_{2}$ emissions will decrease to near zero. However, for NO $_{\text{x}}$ , assuming equal heat supply, the gas fired plant will need higher generation efficiency, leading to even slightly higher NO $_{\text{x}}$ emission levels (Ni, Reference Ni2013). In our analysis, we conservatively assume zero emissions of PM $_{2.5}$ and SO $_{2}$ with intervention, whereas no significant changes in NO $_{\text{x}}$ emissions. For the health endpoint ( $k$ ), we focus on estimating changes in mortality and in morbidity of chronic bronchitis, because the former usually accounts for more than 90% of health benefits, and the latter is usually the second largest (US EPA, 2011).

We now turn to the choice of $\unicode[STIX]{x1D6FD}_{jk}$ . Coal-to-gas for a power plant unit corresponds to a long-term marginal change in PM $_{\text{2.5}}$ concentration. We should, therefore, use C-R functions between long-term ambient air pollution and health endpoints. Evidences show that the C-R function may be concave across wide ranges of exposure (Burnett et al., Reference Burnett, Pope, Ezzati, Olives, Lim, Mehta, Shin, Singh, Hubbell, Brauer, Anderson, Smith, Balmes, Bruce, Kan, Laden, Pruss-Ustun, Turner, Gapstur, Diver and Cohen2014; Pope, Cropper, Coggins & Cohen, Reference Pope, Cropper, Coggins and Cohen2015), implying that a marginal pollution abatement effort may yield less benefits in China compared with developed countries, since the PM $_{2.5}$ concentration is higher in China than in developed countries. Therefore, one should ideally use Chinese cohort mortality evidence, and to the best of our knowledge, at the time this paper was being written, there are two studies providing Chinese long-term exposure mortality evidence (Cao et al., Reference Cao, Yang, Li, Chen, Chen, Gu and Kan2011; Chen, Ebenstein, Greenstone & Li, Reference Chen, Ebenstein, Greenstone and Li2013). The C-R coefficients in these two studies are indeed smaller than those in developed countries, in line with the concave assumption of C-R function. However, the models in Chen et al. (Reference Chen, Ebenstein, Greenstone and Li2013) have been found to be overfitting, resulting in implausible causal inference (Gelman & Zelizer, Reference Gelman and Zelizer2015). Cao et al. (Reference Cao, Yang, Li, Chen, Chen, Gu and Kan2011) is based on total suspended particle (TSP), rather than PM $_{2.5}$ . Thus, applicability of these two studies is limited. Recently, an integrated exposure-response (IER) model was developed by integrating available relative risk (RR) evidences for the whole PM $_{2.5}$ exposure range from ambient air pollution to active smoking (Burnett et al., Reference Burnett, Pope, Ezzati, Olives, Lim, Mehta, Shin, Singh, Hubbell, Brauer, Anderson, Smith, Balmes, Bruce, Kan, Laden, Pruss-Ustun, Turner, Gapstur, Diver and Cohen2014), that can be applied within the range of Chinese ambient PM $_{2.5}$ concentration. However, the RRs in this IER model cannot be directly converted to C-R coefficients, and we therefore, in this paper opt to follow Zhou et al. (Reference Zhou, Fu, Zhuang and Levy2010, Reference Zhou, Hammitt, Fu, Gao, Liu and Levy2014) who have accounted for the effect of lower C-R coefficients in China in an analytical context similar to ours: we use a 1% increase in all-cause mortality per 1- $\unicode[STIX]{x03BC}$ g $/$ m $^{3}$ increase in annual PM $_{2.5}$ concentrations as central estimate, a lower bound of 0.1% and an upper bound of 2.0% in a triangular distribution. It is worth noting that PM $_{2.5}$ health effects overall are very large because there are many sources of PM $_{2.5}$ in big cities like Beijing. Due to the concavity in the C-R function, marginal interventions to reduce PM $_{2.5}$ will have lower benefits now relative to a future where PM $_{2.5}$ emissions from other sources are lowered. And coordinated PM $_{2.5}$ reducing strategies will have greater overall effect than each intervention evaluated individually.

3.3.2 Health effects associated with phasing out household coal use interventions

Most of the research on health effects from household fuel use is based on a “binary exposure classification” which separates the study population into those exposed to certain fuel usage and those not exposed (Desai, Mehta & Smith, Reference Desai, Mehta and Smith2004; Smith et al., Reference Smith, Bruce, Balakrishnan, Adair-Rohani, Balmes, Chafe, Dherani, Hosgood, Mehta, Pope and Rehfuess2014; WHO, 2014). The fraction of disease $k$ in the population by age ( $s$ ) and gender ( $t$ ) group attributable to exposure ( $AF_{kst}$ ) can be calculated by

(4) $$\begin{eqnarray}AF_{kst}=\frac{1}{1+[P_{est}(RR_{kst}-1)]^{-1}},\end{eqnarray}$$

where $P_{est}$ is the percentage of the population exposed and $RR_{kst}$ is the relative risk for disease $k$ . We quantify the three major health outcomes following WHO (2014): acute lower respiratory infection (ALRI) for children under 5 years old, chronic obstructive pulmonary disease (COPD) and lung cancer for adults over 30 years old. Then the health effects from disease $k$ attributable to exposure in the population by age ( $s$ ) and gender ( $t$ ) group ( $E_{kst}$ ) are estimated by,

(5) $$\begin{eqnarray}E_{kst}=AF_{kst}\cdot I_{kst}\cdot Pop_{st},\end{eqnarray}$$

where $Pop_{st}$ is the population size by age $s$ and gender $t$ group. Parallel to that for power plants, we clarify that: improved coal, improved stove, or improved emission ventilation can mitigate exposure level to different extent. We follow Desai et al. (Reference Desai, Mehta and Smith2004) and set a ventilation coefficient (a multiplier of $P_{est}$ ) to account for the variability of the actual exposure level so that we do not overestimate health benefits. Further, for COPD and lung cancer, we only quantify the completely prevented cases. We choose not to quantify those who have developed the early stages of COPD or have accumulated a high risk for lung cancer over many years’ exposure because it is difficult to know to what extent the onset of disease for such individuals could be reduced by an end in exposure (Hutton, Rehfuess, Tediosi & Weiss, Reference Hutton, Rehfuess, Tediosi and Weiss2006). Lastly, similar to that for the power sector, the IER (Burnett et al., Reference Burnett, Pope, Ezzati, Olives, Lim, Mehta, Shin, Singh, Hubbell, Brauer, Anderson, Smith, Balmes, Bruce, Kan, Laden, Pruss-Ustun, Turner, Gapstur, Diver and Cohen2014) provides a possibility to estimate health impacts based on actual indoor PM $_{2.5}$ concentration changes. However, we choose to still adopt the “binary exposure classification” method which only classify exposure by exposed and not exposed to household coal usage. The smoke from household coal combustion is a mixture of PM $_{2.5}$ and many other harmful emissions, which may result in toxicity and health impacts different to that from only PM $_{2.5}$ . Therefore, we utilize the RR evidences for household coal usage in WHO (2014), rather than those for PM $_{2.5}$ in the IER. Similarly, the reason why a full relative risk is used for household coal use, whereas only a more limited set of coal combustion emissions are accounted for in the power plant intervention, is because coal combustion in household coal stoves and in power plants are very different; the latter is much more complete and the end-of-pipe treatments in power plants are effective, therefore generating much less of emissions other than SO $_{2}$ , NO $_{\text{x}}$ and PM.

3.3.3 Monetize health effects

We use the value of a statistical life (VSL) to monetize mortality reductions. VSL is the marginal rate of substitution between mortality risk and income (Hammitt, Reference Hammitt2000). In China ten VSL studies have been conducted to date and the estimates are from US$150,000 to US$800,000 (Huang, Andersson & Zhang, Reference Huang, Andersson and Zhang2015). Currently there is no “official VSL” in China and we therefore use this range for our estimations. For household intervention, we discount the health benefits related with chronic diseases which have a delay of onset. For their mortality reductions, VSL is adjusted based on income growth assumptions (4%–7%, explained in Table A5) over the years between pollution exposure and health effect onset (hereinafter latency), and by income elasticity of VSL (1–2, see Hammitt & Robinson, Reference Hammitt and Robinson2011). The estimated benefits are then multiplied by the discount factor, $e^{-d\cdot r}$ , where $d$ is the years of delay in onset of symptoms (15–25 years) and r is social discount rate. We do not discount for power plants intervention because nearly all of the health impacts of ambient PM $_{2.5}$ were observed within 2 years of exposure, therefore the effect of discounting is minimalFootnote ¹¹ (Levy et al., Reference Levy, Baxter and Schwartz2009). For morbidities related to power plants, we follow US EPA (2011) and set the value of a statistical case (VSC) of chronic bronchitis to be around 5.5% of the VSL. Regarding household morbidity, we apply the same VSC/VSL ratio and discount factor for COPD morbidity reduction. For lung cancer cases, since the probability of dying, conditional on getting this disease, almost equals one, we do not monetize its morbidity risk to avoid double counting. Avoided ALRI is monetized with information on the cost of illness (Ministry of Health of China, 2012).