Linkages between Trade, CO2 Emissions and Healthcare Spending in China

China has remained top among the carbon dioxide (CO2) emitting countries in the world, while it has a significant contribution to world trade after World Trade Organization (WTO) reforms in China. The dramatic increase in CO2 emissions has been witnessed. This study examines the linkages between trade openness, CO2 emissions, and healthcare expenditures in China using time series data for the period 1990–2017. The study extended a theoretical model by adding healthcare expenditures, CO2 emissions, and trade openness with some constraints. We used simultaneous equation method for the analysis, and the outcomes suggest that trade is significantly affecting the CO2 emissions in the country, resulting in an increase of healthcare expenditures. The government needs reforms and trade policy embodied green energy consumption in the industrial sector, especially in export sector industries. In addition, carbon tax may be an important tool to reduce CO2 emissions and it may compensate the healthcare spending in the country.


Introduction
The relationship between trade with carbon dioxide (CO 2 ) and CO 2 with healthcare expenditure are well discussed in the literature. Some studies, including [1][2][3][4][5], explored the linkages between trade and CO 2 . Other studies investigated the relationship between CO 2 and healthcare expenditures [6][7][8][9][10]. Though these studies exclusively address either trade with CO 2 or CO 2 with healthcare expenditures. Nonetheless, a combined effect of trade and CO 2 with healthcare spending is still unexplored. This study aims to fill this research gap by investigating both CO 2 emissions and trade liberalization implications for healthcare expenditures; in addition, this study provides a theoretical model for the association between trade openness, CO 2 emissions and health expenditures. Among other pollutants, CO 2 is the major contributor to environmental pollution; it may have an adverse impact on the social and economic development of a society [1]. Trade affects CO 2 emissions in three major ways: The scale effect, the composition effect, and the technique effect [11,12]. The scale effect represents the increase in CO 2 emissions as a result of trade liberalization and a high level of economic activities, especially in the export sector industries. The composition effect shows the comparative advantage 2 of 15 of trade, the production pattern, as well as industrial structure, which results in the specialization of some industries in which a country has comparative advantages that lead to increased CO 2 emissions. A country's comparative advantage is the main determinant of trade that affects the environment [13]. The technique effect illustrates the CO 2 emissions due to technological spillover in a country, which implies that post-trade openness countries change production patterns towards more technological modes, consequently leading to higher CO 2 emissions in the economy. However, if trade liberalization embodied regulations to control greenhouse-gas in production, then exports may reduce CO 2 emissions in the economy. Carbon dioxide emissions not only decrease the overall environmental health, but also impose a serious cost of healthcare expenditures. The poor environmental quality has a negative impact on human health and an adverse effect on labor productivity [14]. CO 2 emissions are the major factor influencing environmental quality that has adverse implications for the health of society. The medical research found different types of mortalities resulted from environmental pollution, for example, small particulate matter causes work loss and bed disability in adults [15]. Different pollutants like sulfur dioxide and total suspended particulate (TSP) increase mortality rates [16]. The effect of CO 2 on health has significant consequences for healthcare expenditures; though most of the previous literature suggests that income is the primary determinant of health expenditures, CO 2 and poor quality of the environment are also important factors. CO 2 emissions can be considered a negative externality that can lead to potential negative implications for labor productivity, leading to deterioration of industrial output and economic growth. The small particulate matter (PM) causes an increase in sick leave, which indicates a negative effect on health [6,17]. Furthermore, research has found that the effects of other gases, such as sulfur dioxide and nitrogen dioxide, on sick leave of employees are rather ambiguous. Countries with higher pollution have higher healthcare spending, while countries that have higher environmental expenditures have lower expenditures on healthcare [10]. A bidirectional causality between CO 2 emissions and healthcare spending is found for 53 countries [18]. Many other studies, including [19][20][21][22][23][24][25][26], have found a positive relationship between health spending and emissions of pollutants.

Trade Reforms, CO 2 and Healthcare Spending in China
China has made a significant contribution to world trade in the last two decades. It has a major share in world trade, which was recorded as 3% of the total world trade in 1995, and it reached almost 12% of the world trade in 2017. However, after the communist revolution in 1949 followed the self-sufficiency policy until the beginning of economic reforms in 1978, allowing a selected number of firms to engage in foreign trade [25,26]. China gradually moved towards more open trade policies in the early 1980s, and few foreign firms were allowed to trade in specific economic zones located on the east coast [27,28]. Trade was further liberalized with the removal of restrictions in the 1990s and as a result the number of foreign firms increased, reaching up to 35,000 in the mid-1990s [26]. Following the trade liberalization policies, China eventually entered the World Trade Organization (WTO) in December 2001 [27]. Figure 1 depicts the important relationship between CO 2 emissions and exports from 1960 to 2017. There is a dynamic trend between CO 2 emissions and exports in different years, but both are moving with the same path. There is an overall increase in both variables except for a few years where it shows minor deviations. Interestingly, in 2002 when China entered the WTO, there are was a sharp increase in both CO 2 emissions and exports, and these decreased in 2008 due to world economic recessions. During the recovery period, it increased until 2011 and thereafter it showed a moderate decrease in 2014, and remained constant from 2014 to 2017. This figure shows that CO 2 emissions and exports are very closely related, and they follow similar trends in different years, which depicts that exports are the significant determinants of CO 2 emissions in the country. These trade activities excessively affect the CO 2 emissions in China especially from 2000 and onward, and China remained at the top among CO 2 emitting countries.   Figure 2 shows demand-based and production-based CO2 emissions; it has been observed that China place on top among the CO2 emitting countries while the United States is second. The total energy consumption and CO2 emissions of China in 2014 were 4.26 Gtce and 9.76 Gt, respectively, which accounted for global usage of 23.0% and 27.5% of energy consumption and CO2 emissions, respectively [30]. There has been growing concern and attention from the international community on CO2 emissions [31,32]. China has a plan to mitigate its CO2 emissions and has aimed to reduce CO2 emissions by 60%-65% by 2030 [33,34]. Overall, there is an increasing trend of CO2 from 2000 and onward, except in 2008 where the global crises existed, when both imports and exports tended to decrease, the low level of trade activities contributing less CO2 emissions. CO2 emissions and other toxic fumes that discharge into the environment, mainly from manufacturing industries, are the primary sources of pollution that lead to poor air quality and health problems [35].    Figure 2 shows demand-based and production-based CO 2 emissions; it has been observed that China place on top among the CO 2 emitting countries while the United States is second. The total energy consumption and CO 2 emissions of China in 2014 were 4.26 Gtce and 9.76 Gt, respectively, which accounted for global usage of 23.0% and 27.5% of energy consumption and CO 2 emissions, respectively [30]. There has been growing concern and attention from the international community on CO 2 emissions [31,32]. China has a plan to mitigate its CO 2 emissions and has aimed to reduce CO 2 emissions by 60-65% by 2030 [33,34]. Overall, there is an increasing trend of CO 2 from 2000 and onward, except in 2008 where the global crises existed, when both imports and exports tended to decrease, the low level of trade activities contributing less CO 2 emissions. CO 2 emissions and other toxic fumes that discharge into the environment, mainly from manufacturing industries, are the primary sources of pollution that lead to poor air quality and health problems [35].  . There has been growing concern and attention from the international community on CO2 emissions [31,32]. China has a plan to mitigate its CO2 emissions and has aimed to reduce CO2 emissions by 60%-65% by 2030 [33,34]. Overall, there is an increasing trend of CO2 from 2000 and onward, except in 2008 where the global crises existed, when both imports and exports tended to decrease, the low level of trade activities contributing less CO2 emissions. CO2 emissions and other toxic fumes that discharge into the environment, mainly from manufacturing industries, are the primary sources of pollution that lead to poor air quality and health problems [35].      The industrial sector is the main contributor to air pollution in China, which has increased to 69.42 trillion between 2002 and 2014 [36][37][38]. The impact of air pollution and human health has been well explored in the literature [39]. Some of the studies related to China extensively address the industrial air pollution and its adverse effect on human health. For example, air pollution may result in unhealthy birth of babies born, especially to women living near industrial areas; childhood-onset asthma; premature mortality; respiratory disease mortality; childhood-onset asthma; and hospitalizations for respiratory and cardiovascular problems [1,37,[40][41][42]. This adverse implication of CO2 and air pollution are mainly associated with healthcare expenditures; according to the OECD (2016) air pollution was predicted to increase the global economic costs equivalent to 1% of global GDP by 2060 with costs related to additional health care expenditures in the long run [1]. A study suggests that industrial air pollution in China has increased the provisional health care expenditures up to 3% [1]. Apart from other factors, CO2 emissions are one of the main factors responsible for the growing health expenditures in most of the economies. This study is trying to explore the linkages between trade openness, CO2 emissions, and healthcare expenditures by constructing an appropriate theoretical framework and empirical investigation using the case of China. The rest of the paper is organized as follows: Section 2 represents the theoretical framework, Sections 3 and 4 contain the research methodology and results and discussions, respectively, while Section 5 provides a brief conclusion of the study.

Theoretical Framework
The model contains a world of N countries, a representative agent, and a fixed labor supply. Production requires a single factor that is labor, following the Armington model [43] which assumes that each firm engaged in trade produces one variety per sector, which are differentiated by origin of the country. This model uses the Ricardian framework with some more realistic assumptions initially extended by [44,45] that have equivalent welfare outcomes. These models are similar to the Armington model, which determines equilibrium production and consumption. Indeed, the carbon emissions in this framework primarily depend on consumption and production decisions rather than micro-foundations.

Preferences
The consumer assumes to have the preferences of constant elasticity of substitution (CES) type over varieties within a sector. The preferences are presented in quadratic form using the Cobb-Douglas function for CO2 emissions and damage from carbon emissions as follow: The industrial sector is the main contributor to air pollution in China, which has increased to 69.42 trillion between 2002 and 2014 [36][37][38]. The impact of air pollution and human health has been well explored in the literature [39]. Some of the studies related to China extensively address the industrial air pollution and its adverse effect on human health. For example, air pollution may result in unhealthy birth of babies born, especially to women living near industrial areas; childhood-onset asthma; premature mortality; respiratory disease mortality; childhood-onset asthma; and hospitalizations for respiratory and cardiovascular problems [1,37,[40][41][42]. This adverse implication of CO 2 and air pollution are mainly associated with healthcare expenditures; according to the OECD (2016) air pollution was predicted to increase the global economic costs equivalent to 1% of global GDP by 2060 with costs related to additional health care expenditures in the long run [1]. A study suggests that industrial air pollution in China has increased the provisional health care expenditures up to 3% [1]. Apart from other factors, CO 2 emissions are one of the main factors responsible for the growing health expenditures in most of the economies. This study is trying to explore the linkages between trade openness, CO 2 emissions, and healthcare expenditures by constructing an appropriate theoretical framework and empirical investigation using the case of China. The rest of the paper is organized as follows: Section 2 represents the theoretical framework, Sections 3 and 4 contain the research methodology and results and discussions, respectively, while Section 5 provides a brief conclusion of the study.

Theoretical Framework
The model contains a world of N countries, a representative agent, and a fixed labor supply. Production requires a single factor that is labor, following the Armington model [43] which assumes that each firm engaged in trade produces one variety per sector, which are differentiated by origin of the country. This model uses the Ricardian framework with some more realistic assumptions initially extended by [44,45] that have equivalent welfare outcomes. These models are similar to the Armington model, which determines equilibrium production and consumption. Indeed, the carbon emissions in this framework primarily depend on consumption and production decisions rather than micro-foundations.

Preferences
The consumer assumes to have the preferences of constant elasticity of substitution (CES) type over varieties within a sector. The preferences are presented in quadratic form using the Cobb-Douglas function for CO 2 emissions and damage from carbon emissions as follow: The model contains a world of N countries, a representative agent, and a fixed labor supply. Production requires a single factor that is labor, following the Armington model [43] which assumes that each firm engaged in trade produces one variety per sector, which are differentiated by country of origin.. This model uses the Ricardian framework with some more realistic assumptions initially extended by [44,45] that have equivalent welfare outcomes. These models are similar to the Armington model, which determines the equilibrium production and consumption. Indeed, the carbon emissions in this framework primarily depend on consumption and production decisions rather than micro-foundations.
The first equation represents utility from consumption by consuming goods while the second equation shows the disutility arising from carbon emissions. The term Q j d represents CES aggregate of varieties Q j od , which indicates trade from origin country o to destination country d of sector j goods. The σj, is elasticity of substitution between sector j varieties, which is greater than 1. The CES preferences across sectors indicate that the country d spends the share α j d of its expenditure on sector j. E o is the CO 2 emissions from country o, while µ d represents parameters of the social cost of CO 2 emissions. CO 2 emissions are assumed as a pure externality while making the consumption decision. It is also assumed that the negative externality decreases the utility, but it has no direct impact on trade. Following price index for sector j in country d under these preferences as The price index shows that the p j d is the price of j varieties produced in o country and sold in d Here these price indices do not contain the environmental damages and it is assumed that CO 2 emissions are a pure externality.
This paper follows the assumption [5,46] framework for climate damage as it provides insight into how CO 2 emissions affect climate and utility by using a quadratic damage function. In addition, the value µd assesses climate damages, for example, adverse human health resulting from CO 2 emissions, the value of µd and expenditure shares αjd assumed to be varied across the countries.
The model follows indirect utility function as This equation implies that social welfare is determined by the product of real income and environmental damage to the country. This suggests that each country has a different willingness-to-pay for restricting the CO 2 emissions, which means real income for avoiding carbon emissions devoted to the amount of µd in a country.

Technology
The production technology in Cobb-Douglas function and trade cost is assumed like iceberg form, and τ j od ≥ 1 must be shipping country to arriving country as follows: where ω 0 is wages of labor, while p

Technological Spillover and Scale Effect
The technological spillover T od where T od is the technological spillover, which is determined by the initial level of technology or existing technology κ d while new technology transfer κ od from d to j. This function follows z > 1 production elasticities which means the increasing return to scale.

Environment
The environment damage E d , This equation presents how trade contributes to the CO 2 emissions from both the production sector taking as scale effect and technological spillover effect. The χ j o is the CO 2 emissions in j sector for each unit of production and constant γ3. The X j od /p j od is the goods produced in o country while consuming in d country. Trade generates an environmental externality through technological spillover T j od and scale effect χ j o . In addition, the above equation implies that trade can increase pollution intensity through an increase in the production and technological spillover effect. It is further assumed no abatement technologies exist for CO 2 emissions.

Health Expenditures
The Equation (8) shows healthcare expenditures due to CO 2 emissions. H.E represents healthcare expenditures (HE) which is directly related with CO 2 , implying that increase in CO 2 tends to increase the CO 2 . Technological spillover also has a direct association with CO 2 and healthcare expenditure; this means that technological spillover affects the CO 2 as well as healthcare expenditures. The domestic country may impose some restrictions to control the CO 2 emissions, for example, CO 2 tax, which can reduce the CO 2 emissions in the domestic country after trade liberalization and α + β/ω which allows a constant increase between HE, CO 2 , T, and R.

Market Clearing
The consumers aim to maximize utility, while the firm objective is the maximization of profits and for markets to reach equilibrium. The demand is determined through two stages; in the first stage, each country spends the share α j d on sector j, while in the second stage the expenditures are allocated across the varieties within a sector.
Here λ j od shows country d's expenditure of goods produced in country o. The share of country d's expenditure in sector j that is produced in country o. θ j ≡ 1 − σ j represents the trade elasticity of the gravity models [43]. The profit maximization of producers and utility maximization of consumer's lead to the expenditure equation as follows: The country trade imbalances in different sectors and total net exports of a country is equal to the T d , and its magnitude value holds a positive sign which implies trade deficit, while negative sign shows a trade surplus and the parameter ϕ d is the revenue from carbon tax on exports. The parameter φ d indicates financial flow due to carbon tax, where

Materials
This study uses time-series data from 1990 to 2017 which is obtained from World Bank Development Indicators (WDI) [29]. The trade liberalization variable is manually calculated by taking exports and imports ratios to the GDP. CO 2 emissions is collected as metric tons per capita, population growth is annual growth, for the industrial production the proxy of "industry value added (annual % growth)" is taken. For health expenditure we took current health expenditure (% of GDP).

Methods
The system of equation model of our study as follows: where health expenditures (HE) and carbon dioxide emissions (CO 2 ) are n × 1 vectors, from the production sector is taken as proxy for a wide range of environmental pollutants that have adverse implications on human health and trade liberalization (TL); population growth (PG), and industrial production (IP) are n × k 1 and n × k 2 matrices of exogenous variables. The αi and βi are the parameter vectors (i = 1 . . . n) and the ν i error terms (i = 1 . . . n). The model estimations are conditional on TL, PG and IP variables. HE and CO 2 are the endogenous variables that are interdependent and have to be determined jointly as shown in Figure 4.  In order to show specific relationships between the endogenous variables and the exogenous variables, the reduced form of equations can be derived and at the first stage we use matrix form to represent the structural equation.
where is the 2×2 matrix of reduced form of disturbances, which is based on the two initial equations (12) and (13) as follows: The above equations provide the relationship between endogenous variables and exogenous variables. The reduced form equations provide more meaningful and detailed information as compared to structural form equations regarding the total effects of the exogenous variables on the endogenous variables [48].
The ordinary least square (OLS) estimation methodology is not a suitable method for SES model because of simultaneity bias which means that OLS estimation could be inconsistent. In order to avoid this issue, we will use the two-stage least square (2SLS) and three-stage least square (3SLS) methods for the empirical analysis. The 2SLS and 3SLS methods are similar to the instrumental variables (IV) In order to show specific relationships between the endogenous variables and the exogenous variables, the reduced form of equations can be derived and at the first stage we use matrix form to represent the structural equation.
The above equations provide the relationship between endogenous variables and exogenous variables. The reduced form equations provide more meaningful and detailed information as compared to structural form equations regarding the total effects of the exogenous variables on the endogenous variables [47].
The ordinary least square (OLS) estimation methodology is not a suitable method for SES model because of simultaneity bias which means that OLS estimation could be inconsistent. In order to avoid this issue, we will use the two-stage least square (2SLS) and three-stage least square (3SLS) methods for the empirical analysis. The 2SLS and 3SLS methods are similar to the instrumental variables (IV) suggested by [48]. The selection of suitable instruments are required not to be correlated with the error term (ν i ) but strongly associated with endogenous variables [49][50][51][52]

Baseline Estimation
This section illustrates the empirical results of our model as follows. The model-1 reports the 2SLS results in Table 1; taking HE as the dependent variable, while CO 2 emissions, trade liberalization, population growth, and industrial production are the independent variables. The outcomes revealed that one unit increase in CO 2 leads to an increase of the HE by 0.33% significant at 5% level of significance. This implies that CO 2 is one of the important factors to determine health expenditure in the case of China. Trade liberalization did not significantly contribute to health expenditure according to the estimated values of T-statistic and probability value (T-value = 1.334 and P-value = 0.19). This supports the previous studies' findings that income determines CO 2 emissions, and that increased income predicts an increase in healthcare spending also. The impact of population growth on healthcare expenditure is positive and significant at 1% level of significance. This means that higher population growth increases healthcare spending; the results of the present study is an indication of the validation of the Malthusian population trap, in which higher population growth rates predict an increase of health hazards in relation to world resources and world population. While industrial production is found statistically insignificant, this indicates that industrial production is not an important factor in the determination of health expenditure rise in China. The overall model is a good fit represented by the value of R 2 and F-statistics i.e., 0.97 and 310.047, respectively. The value of Durban Watson is 1.88 which shows that there is no serious issue of serial correlation.  Table 2 shows the results of the 2SLS for the CO 2 emission model. Different factors are selected based on past literature. The impact of trade liberalization is found positive and significant at 5% level of significance. This implies that trade activities are responsible for CO 2 emissions in the economy of China. Health expenditure is found positive but insignificant to determine CO 2 emissions. It means that health expenditures have no contribution to the production of CO 2 . Population growth affects CO 2 positively and significantly. Population growth is the leading factor to determine CO 2 , due to deforestation and increasing pressure on natural resources, and a drastic increase in consumption. One percent increase in population growth caused 78.6% CO 2 emission. The impact of factor industrial production on CO 2 is positive and highly significant. One percent increase in industrial production leads CO 2 to increase by 0.841%. This means that industrial production is one of the most important sources of CO 2 emissions in China. The result of the present study is in line with past literature, both empirical and theoretical. The coefficient estimate of R 2 is 0.97, meaning that 97%of the variation in the dependent variable is explained by the variables included in the model.  Table 3 contains 3SLS outcomes; these results are very similar to 2SLS empirical results. In the first equation, HE is the dependent variable, while CO 2 , TL, PG, and industrial production are independent variables. The CO 2 emission is found positive and significant in the determination of health expenditure. Results reported that a 1% increase in CO 2 emissions leads to an increase in the HE by 0.298%. The impact of trade liberalization on health expenditure reported positive and statistically significant at 1% level of significance. The result of the present study is parallel with the existing literature. Results show that the variable industrial production has no association with health expenditure. The F-statistics value is significant, implying that healthcare spending is determined jointly by CO 2 emissions, PG, trade liberalization, and industrial production. The value of R 2 is 0.97%, which indicates that 97% of variations in healthcare spending come from the included variables, while the rest of the variation is devoted to the error term.  Table 4 shows the results provided by 3SLS for the CO 2 emission model. It is clear from the results that trade liberalization affects CO 2 positively and significantly with a probability value of 0.041. This implies that a 1% increase in trade liberalization leads to an increase in CO 2 emission of 0.054%. These results supported the theory, that trade liberalization leads to an increase of CO 2 emissions through scale and technical effect. The health expenditure variable is found insignificant to affect the variation in CO 2 emissions. Furthermore, the variables, population growth and industrial, are found positive and significant at a 1% level of significance. It shows that both the variables are very important in the determination of CO 2 emission, because the coefficient values are high and highly significant. Therefore, both the variables should be put in policy formulation to reduce environmental degradation in the form of low CO 2 emission. The R 2 shows that explanatory variables are explaining the dependent variables by 97% of the dependent variables. The F-statistic has a significant value which implies that all the included variables have a joint effect on CO 2 determination.

Robustness Test
The Granger causality results presented in Table 5 shows the causal relationship between the variables included in the model. Results reported that there is unidirectional causality from CO 2 and HE, running from CO 2 to HE, which implies that CO 2 emissions tend to increase the healthcare expenditures. A unidirectional causality runs from trade liberalization to CO 2 emission. No causal relationship reported by Granger causality between trade liberalization and health expenditure was detected, while causality runs from trade liberalization to CO 2 emission, and from CO 2 to health expenditure. Population growth also causes CO 2 emission and trade liberalization. Population growth causes health care expenditure. Industrial production causes CO 2 emission and also causes trade openness. Trade openness causes CO 2 , which indicates that trade openness leads to CO 2 emission in the country. The empirical findings of 2SLS, 3SLS and Granger causality are presented in Figure 5. . Figure 5. Path diagram of the empirical analysis.

OLS Results
We ran two separate OLS models for HE and CO2. In the first model HE was the dependent variable whereas PG was taken as independent variable. While in the second model CO2 was the dependent variable and IP and PG were taken as independent variables. The results of OLS models are used to compare the AIC values with baseline (2SLS and 3SLS) models. The Akaike Info Criterion (AIC) provides information for better model selection. The baseline equation has AIC value 31.98, while OLS has AIC value 42.21 and 43.56 in first and second model, respectively, which implies that the baseline model is the best fit model compared to simple OLS, and it suggests that trade is an influencing and important factor.

OLS Results
We ran two separate OLS models for HE and CO 2 . In the first model HE was the dependent variable whereas PG was taken as independent variable. While in the second model CO 2 was the dependent variable and IP and PG were taken as independent variables. The results of OLS models are used to compare the AIC values with baseline (2SLS and 3SLS) models. The Akaike Info Criterion (AIC) provides information for better model selection. The baseline equation has AIC value 31.98, while OLS has AIC value 42.21 and 43.56 in first and second model, respectively, which implies that the baseline model is the best fit model compared to simple OLS, and it suggests that trade is an influencing and important factor.

Conclusions
China, on one hand, remained top in CO 2 emitting countries from the last two decades. On the other hand, it has become a large exporting country in the world. It signed the WTO in 2000 and a dramatic increase has been witnessed thereafter, both in export and import sectors. The relationship between trade and CO 2 emissions is well addressed in the literature and trade openness leads to CO 2 emissions, which is empirically tested in various studies. The CO 2 emissions have severe consequences on environment quality and environmental health which leads to health-related issues, and thereby raises healthcare spending both at the individual and public levels. This paper aims to understand the linkages between trade openness, CO 2 emissions, and healthcare expenditures using the case of China. We purposed a theoretical model that shows the linkages between trade, CO 2 emissions, and healthcare expenditures. The model suggests that trade affects CO 2 by two main channels; one is the technological spillover and the other is scale effect; large CO 2 emissions also lead to increased healthcare spending in the country. The scale effect has a definite effect on income, which is supported by previous literature as a high level of income increases the demand for quality of health and thus rising healthcare spending.
The study used a simultaneous equation modeling approach for the empirical analysis to test the theoretical model; we applied 2SLS and 3SLS methodologies by taking healthcare expenditures as dependent variable in the first equation, which was determined by the CO 2 emissions and healthcare spending, while CO 2 emissions from the production sector were taken as proxy for the wide range of environmental pollutants that have adverse implications on human health. The second equation took CO 2 as the dependent variable, and trade openness, industrial production, and population growth were taken as independent variables. The empirical outcomes showed that CO 2 is the main determinant of healthcare expenditures in China. We concluded that trade openness is the main source of CO 2 emissions in China that leads to a high level of health expenditures. Furthermore, industrial production and population growth also contributed to CO 2 emission. The results of this study resemble the findings of [6,36].
This study also has policy recommendations: (a) The Chinese government may reduce CO 2 emissions by appropriate industrial production and trade liberalization policies. Along with industrial and trade policies, the government should pay special attention to those industries which have a large contribution to CO 2 emission. They should impose a carbon tax to reduce CO 2 emissions. (b) The government may promote incentives to use green energy for the production process, which will not only reduce sCO 2 emissions, but may also be helpful in minimizing the health costs raised due to CO 2 emissions, and could provide a healthy environment for society. This study does not support the reduction of health expenditures because it improves the labor productivity and has significant implications for the labor life expectancy. Rather, it recommends accommodating the healthcare expenditures with alternate resources like renewable energies and new technologies that emit a low level of CO 2 emissions. (c) In addition, government legislation for the CO 2 control could be an appropriate tool and the government could bring CO 2 emissions to the desirable level specifically in the exporting industry which will balance the healthcare expenditures, CO 2 emission in the economy.
This study has some limitations; firstly, the transportation technologies are assumed to be constants, which varies across countries and may have implications for the CO 2 emissions. Secondly, this study only focused on a single country case which can be extended to multiple countries. Regional disparities in Chinese provinces for trade activities, CO 2, and health expenditures are also treated as constant, which has diverse implications. Both theoretical and empirical models may further extend to some other factors like life expectancy.