key: cord-0754985-itrkqqar authors: Zhang, Qi; Zhang, Xinxin; Cui, Qi; Cao, Weining; He, Ling; Zhou, Yexin; Li, Xiaofan; Fan, Yunpeng title: The Unequal Effect of the COVID-19 Pandemic on the Labour Market and Income Inequality in China: A Multisectoral CGE Model Analysis Coupled with a Micro-Simulation Approach date: 2022-01-25 journal: Int J Environ Res Public Health DOI: 10.3390/ijerph19031320 sha: 65d337fe3bd37b8d4c91fd05e76aae476230657f doc_id: 754985 cord_uid: itrkqqar The COVID-19 pandemic had an unequal impact on the employment and earnings of different labourers, consequently affecting households’ per capita income and income inequality. Combining a multisector computable general equilibrium model of China with a micro-simulation approach, this study aims to analyse the unequal effect of the COVID-19 pandemic on China’s labour market and income inequality. The results confirm the unequal impact of the pandemic on the employment and earnings of different labourer types. Labourers who are female, live in urban areas, and have relatively low education levels would suffer greater losses in employment and earnings. The pandemic would reduce household per capita income by 8.75% for rural residents and 6.13% for urban residents. While the pandemic would have a larger negative impact on the employment and earnings of urban labourers, it would have a greater negative impact on the household per capita income of rural residents. Moreover, the per capita income of low-income households is more vulnerable to the pandemic, and the number of residents living below the poverty line would increase significantly. Thus, the pandemic would aggravate income inequality in China and threaten the livelihoods of poor families. This study could inform researchers exploring the distributional effect of the COVID-19 pandemic in developing countries. As one of the most significant global public health crises in recent decades, the COVID-19 pandemic posed severe threats to residential health and economy. Strict social distancing and massive shutdown of economic activities during the pandemic reduced enterprises' production and decreased consumer expenditure, inflicting a severe shock to China's economy [1] [2] [3] . In 2020, China's GDP grew by only 2.3% [4] , much lower than the projected growth rate, assuming no pandemic (6.0% [5] ). The pandemic also triggered considerable shocks to China's labour market. Numerous labourers lost their jobs, and the unemployment rate in urban areas reached 4.2% in 2020, 0.6 percentage points higher than that in 2019 [4] . The annual salary in non-private enterprises grew by 5.2% in 2020, the lowest since 1984, while in private enterprises, it grew by 5.3%, the second lowest since 2009. an employee-tracking survey in China. Moreover, several sectors, including construction, education, hotels, and restaurants, had much more significant employment losses, as they were directly exposed to the pandemic [27] [28] [29] [30] . An increasing number of studies explored the unequal impact of the COVID-19 pandemic on the employment and earnings of different labourers [10] [11] [12] [13] [14] [15] [16] [31] [32] [33] [34] . Hoshi et al. [31] found that unemployment was more severe for the non-regular workers, those with low education levels, females, and those aged 31 to 45 years in Japan. Mongey, Pilossoph, and Weinberg [10] suggested that workers who are less educated and have lower incomes and fewer liquid assets were more economically vulnerable to the pandemic in the United States. Hoehn-Velasco, Silverio-Murillo, and Miyar [11] found that the most affected labourers included the youngest, oldest, low-income earners, those hired by small-and medium-sized firms, and those engaged in hospitality-focused services. Furthermore, several studies have suggested that female labourers were more significantly affected by the pandemic than their male counterparts [12] [13] [14] [15] . For example, Albanesi and Kim [15] found that female workers, especially those that have born children, experienced a more substantial employment reduction than male workers. Graeber, Kritikos, and Seebauer [12] also suggested that female labourers were about one-third more likely to experience income losses than their male counterparts. As for China, previous studies have scarcely analysed the unequal impact of the COVID-19 pandemic on the employment and earnings of labourers with different features. The only exception is Che, Du, and Chan [16] , who suggested that migrant rural workers in China who are less educated and less skilled had a higher rate of unemployment. By affecting the per capita income of different households, the COVID-19 pandemic likely increased income inequality in China. On the one hand, rural residents may suffer greater income losses relative to urban residents, as rural workers are less employed on a salary basis, and migrant workers from rural areas are confined to their villages and unable to return to work in cities [8, 20] . The sudden reduction or halt in remittance flows from migrant workers would further reduce the income of rural households [21, 35] . On the other hand, as the pandemic has a more significant negative impact on the low-income households than their advantaged counterparts, it may exacerbate income inequality [17] [18] [19] [36] [37] [38] . Almeida et al. [19] found that the COVID-19 pandemic was likely to significantly affect households' disposable income in the European Union, with lower-income households being more severely hit. Delaporte, Escobar, and Pea [37] found that the pandemic would deteriorate the income of low-income households more severely and push numerous households into poverty. A survey conducted by Luo et al. [38] demonstrated that 7.1% of rural households in China would possibly fall into poverty due to the pandemic, and 23% who had escaped poverty were likely to fall back. As it is challenging to incorporate a large number of representative households into the traditional CGE models, several studies have used an integrated methodology, combining the CGE models and the micro-simulation approaches, to analyse changes in household incomes caused by exogenous shocks [39] [40] [41] [42] . Based on the simulation results of the CGE models, the micro-simulation approach can calculate the changes in income of numerous households with different features [43] . Wang et al. [40] used a recursive dynamic CGE model with a top-down behavioural micro-simulation approach and indicated that population ageing negatively impacts China's poverty reduction but benefits income equality. Heyndrickx, Vanheukelom, and Proost [42] combined a regional CGE model and a household micro-simulation approach to assess the distributional effects of transport tax reform. van Ruijven, O' Neill, and Chateau [44] used a global CGE model and a top-down micro-simulation approach to analyse the consequences of climate change and climate policy on different household types (based on their income level, expenditure pattern, and other socioeconomic characteristics). These studies have illustrated the effectiveness of the micro-simulation approach in examining the impacts of exogenous shocks on household income and income inequality. Previous studies have contributed to the understanding of the pandemic impact on the labour market and household income and explored changes in income inequality preliminarily. However, most of them have focused on the pandemic impact on the labour market and household income in developed countries. The unequal impact of the COVID-19 pandemic on China's labour market has not been investigated comprehensively. Furthermore, existing literature shows that rural residents may suffer greater income losses relative to urban ones, exacerbating the income disparity between urban and rural residents. Previous studies did not quantitatively probe the impact of the COVID-19 pandemic on income inequality between/among urban and rural residents in China. As shown in Figure 1 , this study combines a multisector CGE model with a microsimulation approach and assesses the unequal impact of the COVID-19 pandemic on the labour market and income inequality in China. the effectiveness of the micro-simulation approach in examining the impacts of exogenous shocks on household income and income inequality. Previous studies have contributed to the understanding of the pandemic impact on the labour market and household income and explored changes in income inequality preliminarily. However, most of them have focused on the pandemic impact on the labour market and household income in developed countries. The unequal impact of the COVID-19 pandemic on China's labour market has not been investigated comprehensively. Furthermore, existing literature shows that rural residents may suffer greater income losses relative to urban ones, exacerbating the income disparity between urban and rural residents. Previous studies did not quantitatively probe the impact of the COVID-19 pandemic on income inequality between/among urban and rural residents in China. As shown in Figure 1 , this study combines a multisector CGE model with a microsimulation approach and assesses the unequal impact of the COVID-19 pandemic on the labour market and income inequality in China. Several studies have used CGE models to analyse the economic impacts of infectious diseases [26, 45, 46] . Following them, this study employs a multisectoral CGE model, CHINAGEM, to evaluate the effects of the COVID-19 pandemic on the employment and earnings of different labourers in China. The model was developed by the Institute of Science and Development, Chinese Academy of Sciences, and Centre of Policy Studies, Victoria University of Australia [47, 48] . The CHINAGEM model is a comparative static analysis model, assuming that the market is perfectly competitive and there are constant returns to scale. All product and input markets are cleared so that the equilibrium of total supply and demand determines endogenous variables, such as price, wages, and land rent. There are six economic agents (production, investment, consumption, government, foreign, and inventory) and three primary factors (labour, capital, and land). The theoretical framework of the CHINAGEM model is shown in Figure 2 . For detailed formulas, refer to Cui et al. [49] and Cui et al. [26] . Several studies have used CGE models to analyse the economic impacts of infectious diseases [26, 45, 46] . Following them, this study employs a multisectoral CGE model, CHINAGEM, to evaluate the effects of the COVID-19 pandemic on the employment and earnings of different labourers in China. The model was developed by the Institute of Science and Development, Chinese Academy of Sciences, and Centre of Policy Studies, Victoria University of Australia [47, 48] . The CHINAGEM model is a comparative static analysis model, assuming that the market is perfectly competitive and there are constant returns to scale. All product and input markets are cleared so that the equilibrium of total supply and demand determines endogenous variables, such as price, wages, and land rent. There are six economic agents (production, investment, consumption, government, foreign, and inventory) and three primary factors (labour, capital, and land). The theoretical framework of the CHINAGEM model is shown in Figure 2 . For detailed formulas, refer to Cui et al. [49] and Cui et al. [26] . To save space, this study briefly introduces the nesting structure of the inputs for the producing sectors ( Figure 3) . On the top level, the total input of each producing sector is composed of the primary factor and intermediate inputs, which is depicted by a Leontief function, assuming that their utilisation is fixed proportionally to the total input. On the next level, the primary factor input consists of labour, capital, and land, as depicted by the constant elasticity of substitution (CES) function with a substitution elasticity of 0.5. The intermediate goods include domestic and foreign goods according to the Armington assumption, suggesting that domestically produced goods and foreign goods have incomplete substitution. On the bottom, following Mu et al. [50] , the labour input of each producing sector is split into 24 types along with three properties of labourers. These properties include the living areas (urban or rural), gender (male or female), and education levels (elementary school, middle school, high school, junior college, regular college, and postgraduate). By combining the three properties, 24 labourer types are obtained (2 × 2 × 6 = 24). A CES function is employed to describe the substitution between different types of labourers with an elasticity of 0.5. To establish the database of the CHINAGEM model, this study uses China's recently published input-output table with the base year of 2017 [51] , which provides the total labour input of 149 producing sectors. Then, the total labour input of each sector is split into 24 labourer types based on two datasets. First, the 6th Chinese Population Census (CPC 2010), conducted in 2010, provided the employment quantity for 24 labourer types in 19 To save space, this study briefly introduces the nesting structure of the inputs for the producing sectors ( Figure 3) . On the top level, the total input of each producing sector is composed of the primary factor and intermediate inputs, which is depicted by a Leontief function, assuming that their utilisation is fixed proportionally to the total input. On the next level, the primary factor input consists of labour, capital, and land, as depicted by the constant elasticity of substitution (CES) function with a substitution elasticity of 0.5. The intermediate goods include domestic and foreign goods according to the Armington assumption, suggesting that domestically produced goods and foreign goods have incomplete substitution. On the bottom, following Mu et al. [50] , the labour input of each producing sector is split into 24 types along with three properties of labourers. These properties include the living areas (urban or rural), gender (male or female), and education levels (elementary school, middle school, high school, junior college, regular college, and postgraduate). By combining the three properties, 24 labourer types are obtained (2 × 2 × 6 = 24). A CES function is employed to describe the substitution between different types of labourers with an elasticity of 0.5. To save space, this study briefly introduces the nesting structure of the inputs for the producing sectors ( Figure 3) . On the top level, the total input of each producing sector is composed of the primary factor and intermediate inputs, which is depicted by a Leontief function, assuming that their utilisation is fixed proportionally to the total input. On the next level, the primary factor input consists of labour, capital, and land, as depicted by the constant elasticity of substitution (CES) function with a substitution elasticity of 0.5. The intermediate goods include domestic and foreign goods according to the Armington assumption, suggesting that domestically produced goods and foreign goods have incomplete substitution. On the bottom, following Mu et al. [50] , the labour input of each producing sector is split into 24 types along with three properties of labourers. These properties include the living areas (urban or rural), gender (male or female), and education levels (elementary school, middle school, high school, junior college, regular college, and postgraduate). By combining the three properties, 24 labourer types are obtained (2 × 2 × 6 = 24). A CES function is employed to describe the substitution between different types of labourers with an elasticity of 0.5. To establish the database of the CHINAGEM model, this study uses China's recently published input-output table with the base year of 2017 [51] , which provides the total labour input of 149 producing sectors. Then, the total labour input of each sector is split into 24 labourer types based on two datasets. First, the 6th Chinese Population Census (CPC 2010), conducted in 2010, provided the employment quantity for 24 labourer types in 19 To establish the database of the CHINAGEM model, this study uses China's recently published input-output table with the base year of 2017 [51] , which provides the total labour input of 149 producing sectors. Then, the total labour input of each sector is split into 24 labourer types based on two datasets. (Table A1) , the average wage of each labourer type (Wage ij ) is calculated for these aggregated sectors based on the CHIP 2013 database. The earnings (Earning ij ) gained by 24 labourer types from 19 aggregated sectors are obtained by multiplying the employment quantity (Employment ij ) with the average wage. In Equation (1), i indexes the labourer type, and j indexes the aggregated sector. For each of the 19 aggregated sectors, the weight of the earnings is gained by each labourer type from the sector's total labour input (W ij ). By mapping the 19 aggregated sectors of the CPC 2010 to 149 sectors of the 2017 inputoutput table (see Appendix A), the earnings gained by each labourer type is calculated by multiplying the weight matrix (W ij ) with the total labour input (Labour im ) of the mapped subdivided sectors m. The m indexes the sector from the 2017 input-output table that is mapped with the aggregated sector j. Finally, a matrix is obtained for the earnings gained by 24 labourer types from the 149 sectors (L_Earning im ). As for the closure of the simulation, this study, consistent with previous studies, analyses the damages caused by the COVID-19 pandemic in the short term. Capital is exogenous in producing sectors with a sectoral-differentiated rate of return ( Figure 2 ). The real wage is unchanged while allowing for unemployment. Tax rates and technology are determined exogenously. Although the CHINAGEM model could simulate the unequal impact of the COVID-19 pandemic on employment and earnings for different labourer types, it is difficult to reveal the effects on household income and the income equality. Household income is from the factor rents (including labour and capital) and transfer income from both government and non-government institutions. The CGE models could simulate the changes in the employment and income of labourers; however, they could not directly estimate the income changes of households with different features. Several studies have coupled the CGE models with the micro-simulation approach, transferring the simulated macroeconomic results to the microdata covering numerous households to simulate the impact of policies on household income and the income equality [40, 52, 53] . Following these studies, the CHINAGEM model is combined with a micro-simulation approach to simulate the impact of the COVID-19 pandemic on household income and the income inequality in China. As reviewed by Debowicz [53] , previous studies developed two methods to link CGE models with the microdata, including the integrated link and layered link. The former integrates the microdata into the CGE model and works well when there are small groups in the models. However, within-group changes in income distribution cannot be considered because the households in the same group are assumed to be unified. The latter solves this problem and contains the behaviour-layered link and non-behaviour-layered link methods depending on whether all the households in a group are affected in the same way by changes in the macro variables [40] . The behaviour-layered link method is further divided into the top-down micro-simulation [43, 53] and the bottom-up microsimulation [52] . Following Wang et al. [40] , this study employs the non-behaviour-layered method for the top-down micro-simulation. The total income of each household is defined in Equation (4): where YH is the total income of each household, which is the summation of labour income and non-labour income; N is the number of family members within a household. For the former, the household's labour income is the summation of the earnings gained by family members. D i is a dummy variable representing the family member's work status: it equals 1 if the member has a job; otherwise, it is 0. The non-labour income of the household, Y NL 0 , includes capital income and the income transferred from government and non-government institutions. The CHIP 2013 database provides data on the labour income of family members and non-labour income for each household, used to calculate the indicators measuring income inequality, such as the Gini coefficient and Lorenz curve. It is regarded as a benchmark for household income without the COVID-19 pandemic. The CGE model provides the impact of the pandemic on the earnings gained by 24 labourer types from 149 producing sectors. Following Wang et al. [40] , the labour incomes of family members are linked with the changes in earnings by labourer type and industry via the top-down non-behaviourlayered link (Equation (5)) and calculate the labour income of family members considering the effects of the pandemic. wherel_earning m is the percentage change in earnings earned by the labourer type i from industry m, estimated by the CHINAGEM model. As the changes in households' nonlabour income could not be estimated from the CGE model, this study assumes that the non-labour income remains unchanged. Household income under the COVID-19 pandemic can then be calculated (Equation (6)). Then, the income inequality indicators are also calculated, including the Gini coefficient and Lorenz curve. Comparing household income and the income inequality indicators with and without the pandemic, this study can assess the impact of the COVID-19 pandemic on household income and income inequality. To establish the scenarios of the COVID pandemic, previous studies considered the multiple shocks of the COVID-19 pandemic to the economy, including the reduction of labour productivity, the loss of labour forces, the increase in investment premium, the decrease in household consumption, and the increase in protective costs [26] . Further, some studies incorporated governmental countermeasures into the scenario design [54] . Following these studies, this study establishes a scenario for the pandemic considering three types of economic shocks and three types of governmental countermeasures and quantifies the shocks based on the statistical data of 2020 in China as follows: (1) The labour productivity of the production sectors declined by 5.60%. The nationwide extension of the spring festival vacation, insufficient operation, and strict social distancing hindered the spread of the pandemic effectively but also lowered the labour productivity of the production sectors. The loss of workdays is calculated as the negative shock to the labour productivity of the producing sectors. As estimated by Zheng et al. [55] , labourers' workdays in 2020 fell by 5.60% in China. (2) The risk premium for investment increased by 1.16%. The pandemic posed a significant risk to investment, which significantly increased the costs of investment. As a higher risk premium of investment is required, following McKibbin and Fernando [54] , this study assumes that the investment risk premium in China increased by 1.16%. (3) Households' total expenditures dropped by 4.83% [4] . Influenced by the pandemic, households significantly reduced their consumption expenditure, especially on accommodation and food services, textiles, clothes, and transport equipment. In addition to the negative impact on household expenditure, the pandemic had a different impact on consumer goods. The shocks are obtained for the consumption of food (3.92%), clothing and shoes (−8.48%), retail (−3.63%), transportation (−4.20%), accommodation (2.57%), food service (−17.03%), and culture and entertainment (−19.74%) in 2020. (4) Three types of governmental countermeasures are considered, such as the governmental procurement, tax relief, and liquidity release. Following Zhou et al. [56] , the shocks on these countermeasures are quantified. China's government increased its spending on clinical and health services by 4.0% and social welfare by 8.2% in 2020. Simultaneously, the government reduced the value-added tax levied on the pandemic prevention and control materials by 8-48%. The government also released liquidity in the capital market to stimulate the economy by reducing the bidding rate of 7-day and 14-day reverse repurchases in the open market by 2.40% and 2.55%, respectively. This consequently reduced the financing cost of firms by approximately 4%. Consistent with expectations, the COVID-19 pandemic severely hurt China's macroeconomy ( Figure 4 ). The pandemic lowered industrial output and triggered unemployment by reducing sectorial labour productivity, total investment, and household consumption, thereby negatively affecting China's GDP. Although governmental countermeasures could mitigate economic damages, they could not buffer the economic losses completely. The national GDP is projected to decrease by 3.77%. Compared with the IMF's projection for China's GDP in 2020 before the pandemic (6% [5] ), our simulation result indicates that China's GDP would grow by 2.23% in 2020, which is much near to the official statistics (2.3%). Further, the pandemic would reduce total investment and household consumption by 0.45% and 7.21%, respectively. Due to the increased expenditure on health and social security, the governmental expenditure would rise by 1.66%. Meanwhile, the pandemic would raise imports by 4.77% and reduce exports by 2.28%. Total employment would fall by 6.72%. In addition, the pandemic would raise the consumer price index (CPI) by 4.39%. (3) Households' total expenditures dropped by 4.83% [4] . Influenced by the pandemic, households significantly reduced their consumption expenditure, especially on accommodation and food services, textiles, clothes, and transport equipment. In addition to the negative impact on household expenditure, the pandemic had a different impact on consumer goods. The shocks are obtained for the consumption of food (3.92%), clothing and shoes (−8.48%), retail (−3.63%), transportation (−4.20%), accommodation (2.57%), food service (−17.03%), and culture and entertainment (−19.74%) in 2020. (4) Three types of governmental countermeasures are considered, such as the governmental procurement, tax relief, and liquidity release. Following Zhou et al. [56] , the shocks on these countermeasures are quantified. China's government increased its spending on clinical and health services by 4.0% and social welfare by 8.2% in 2020. Simultaneously, the government reduced the value-added tax levied on the pandemic prevention and control materials by 8-48%. The government also released liquidity in the capital market to stimulate the economy by reducing the bidding rate of 7-day and 14-day reverse repurchases in the open market by 2.40% and 2.55%, respectively. This consequently reduced the financing cost of firms by approximately 4%. Consistent with expectations, the COVID-19 pandemic severely hurt China's macroeconomy ( Figure 4) . The pandemic lowered industrial output and triggered unemployment by reducing sectorial labour productivity, total investment, and household consumption, thereby negatively affecting China's GDP. Although governmental countermeasures could mitigate economic damages, they could not buffer the economic losses completely. The national GDP is projected to decrease by 3.77%. Compared with the IMF's projection for China's GDP in 2020 before the pandemic (6% [5] ), our simulation result indicates that China's GDP would grow by 2.23% in 2020, which is much near to the official statistics (2.3%). Further, the pandemic would reduce total investment and household consumption by 0.45% and 7.21%, respectively. Due to the increased expenditure on health and social security, the governmental expenditure would rise by 1.66%. Meanwhile, the pandemic would raise imports by 4.77% and reduce exports by 2.28%. Total employment would fall by 6.72%. In addition, the pandemic would raise the consumer price index (CPI) by 4.39%. To show the simulation results clearly, the output changes of 149 original sectors are aggregated to 19 aggregated sectors weighted by sectorial output values. The COVID-19 pandemic has a far-reaching, unequal impact on the output value of producing sectors. The output value of the producing sectors would decline by an average of 3.75% ( Figure 5 ). Among them, accommodation and food services (ACC) would have the largest output reduction (−12.23%). Following the ACC, the output value of the residential services (RES), real estate (REE), finance (FIN), and agriculture (AFF) would also be largely damaged (fall by over 5%). Compared with these sectors, the pandemic would slightly reduce the output value of public administration (SSP), construction (CST), and scientific research and development (STG) by less than 2%. Furthermore, the output value of health and social welfare (HSW) is positively affected by the pandemic, as the government expanded its expenditure on clinical and health services. To show the simulation results clearly, the output changes of 149 original sectors a aggregated to 19 aggregated sectors weighted by sectorial output values. The COVIDpandemic has a far-reaching, unequal impact on the output value of producing secto The output value of the producing sectors would decline by an average of 3.75% (Figu 5). Among them, accommodation and food services (ACC) would have the largest outp reduction (−12.23%). Following the ACC, the output value of the residential servic (RES), real estate (REE), finance (FIN), and agriculture (AFF) would also be largely dam aged (fall by over 5%). Compared with these sectors, the pandemic would slightly redu the output value of public administration (SSP), construction (CST), and scientific resear and development (STG) by less than 2%. Furthermore, the output value of health an social welfare (HSW) is positively affected by the pandemic, as the government expand its expenditure on clinical and health services. The COVID-19 pandemic would negatively affect labourer employment and ear ings for most producing sectors, which are highly consistent with output losses of t sectors ( Figure 6 ). The pandemic would reduce the output value of producing sectors an cut down their demand for labour input, resulting in a decrease in labourer employme and earnings. Furthermore, sectors with larger output losses would have a greater redu tion in employment and earnings. For example, real estate (REE) and accommodation a food services (ACC) would have the largest decreases in employment, falling by 26.27 and 20.47%, respectively. On the one hand, the pandemic would damage the output val of these sectors, directly reducing their demand for labour input. On the other hand, the sectors are labour-intensive, as labour accounts for a high proportion of their producti costs. Hence, the employment of these sectors would decline significantly. According the earnings gained by labourers from the REE and ACC would decline by 28.55% a 22.45%, respectively. Following the REE and ACC sectors, the employment of energy a water supply (EGW) and finance (FIN) would decline by 10.58% and 10.27%, respective The output decreases of these sectors would also reduce their demand for labour inp resulting in a significant reduction in employment. Accompanied with employment d creases, the earnings gained by labourers from EGW and FIN would fall by 6.19% a 12.25%, respectively. Hence, the pandemic would significantly reduce the employme and earnings of labourers for most producing sectors. The COVID-19 pandemic would negatively affect labourer employment and earnings for most producing sectors, which are highly consistent with output losses of the sectors ( Figure 6 ). The pandemic would reduce the output value of producing sectors and cut down their demand for labour input, resulting in a decrease in labourer employment and earnings. Furthermore, sectors with larger output losses would have a greater reduction in employment and earnings. For example, real estate (REE) and accommodation and food services (ACC) would have the largest decreases in employment, falling by 26.27% and 20.47%, respectively. On the one hand, the pandemic would damage the output value of these sectors, directly reducing their demand for labour input. On the other hand, these sectors are labour-intensive, as labour accounts for a high proportion of their production costs. Hence, the employment of these sectors would decline significantly. Accordingly, the earnings gained by labourers from the REE and ACC would decline by 28.55% and 22.45%, respectively. Following the REE and ACC sectors, the employment of energy and water supply (EGW) and finance (FIN) would decline by 10.58% and 10.27%, respectively. The output decreases of these sectors would also reduce their demand for labour input, resulting in a significant reduction in employment. Accompanied with employment decreases, the earnings gained by labourers from EGW and FIN would fall by 6.19% and 12.25%, respectively. Hence, the pandemic would significantly reduce the employment and earnings of labourers for most producing sectors. and entertainment (CSE). As the pandemic has a relatively slighter impact on the outpu of these sectors, their demand for labour input would also decline slightly. The labou employment of these sectors would decrease by less than 3%, accompanied by a decrea in earnings of less than 5%. In addition, the labourer employment in health and soc welfare (HSW) would increase by 4.36% because the government expanded the expen ture on health and clinical services, which consequently increased the demand for labo input of the HSW. The earnings gained by labourers from the HSW would rise by 8.37 The unequal impact of the COVID-19 pandemic on the employment and earnings different labourer types are also examined. Owing to the employment structure of diff ent sectors, the pandemic would have heterogeneous effects on the employment and ear ings of different labourer types (Table 1) . This study also finds that the COVID-19 pandemic would have a relatively lower impact on labourer employment and earnings in several sectors, including public administration (SSP), construction (CST), scientific research and development (STG), and culture and entertainment (CSE). As the pandemic has a relatively slighter impact on the outputs of these sectors, their demand for labour input would also decline slightly. The labourer employment of these sectors would decrease by less than 3%, accompanied by a decrease in earnings of less than 5%. In addition, the labourer employment in health and social welfare (HSW) would increase by 4.36% because the government expanded the expenditure on health and clinical services, which consequently increased the demand for labour input of the HSW. The earnings gained by labourers from the HSW would rise by 8.37%. The unequal impact of the COVID-19 pandemic on the employment and earnings of different labourer types are also examined. Owing to the employment structure of different sectors, the pandemic would have heterogeneous effects on the employment and earnings of different labourer types (Table 1) . First, labourers in urban areas would suffer larger damages from the COVID-19 pandemic to their employment and earnings than their counterparts in rural areas. The em-ployment of labourers in urban areas would decline by an average of 6.60%, accompanied by an average decrease of 7.03% in earnings. Meanwhile, the employment and earnings of labourers in rural areas would fall by an average of 6.16% and 5.44%, respectively. This could be mainly explained by two factors. First, urban areas hosted a larger proportion of producing sectors largely damaged by the pandemic, such as the ACC, RES, and REE. Second, urban labourers accounted for a larger proportion of the labour input in these sectors. In contrast, the output of sectors that are more likely to hire rural labourers, such as the AFF and CST, are relatively slightly damaged by the pandemic. This finding may be attributable to other factors that are not depicted by the CHINAGEM model. For example, the population living in an urban area has a higher risk of severe infection (hospitalisation or mortality) [57] . Second, female labourers would suffer slightly larger damages to their employment and earnings than male labourers, which is consistent with previous studies [12] [13] [14] . The employment of female labourers would decline by an average of 6.55%, accompanied by an average decrease of 6.42% in earnings. Meanwhile, the employment and earnings of male labourers would fall by an average of 6.21% and 6.05%, respectively. While the male is at a higher risk of severe infection [57] , our findings are evidenced by the fact that female labourers accounted for a larger proportion of labour input in the primarily affected sectors, such as the ACC and RES. Third, labourers with relatively low education levels would experience significantly larger decreases in employment and earnings than their counterparts with high education levels. In urban areas, labourers with education levels below high school would suffer employment and earnings losses by over 7% for both male and female labourers. Meanwhile, labourers with education levels above junior college would suffer much smaller losses in their employment and earnings. Similarly, in rural areas, labourers with education levels below high school would have a decrease in employment and earnings of over 6%, much larger than those with education levels above junior college. To conclude, labourers who are the female, live in urban areas, and have low education levels would suffer the largest losses in their employment and earnings. Comparably, labourers with high education levels would experience smaller decreases in their employment and earnings, regardless of their living regions and gender. To analyse the impact of the COVID-19 pandemic on household income and income inequality, the micro-simulation method is applied to the CHIP 2013 database containing 19,798 urban residents in 6674 households and 38,945 rural residents in 10,490 households. Among the residents, 10,119 urban labourers and 16,483 rural labourers are in off-farm jobs. Based on the percentage changes in earnings of different labourer types simulated by the CHINAGEM model, the changes in household per capita income are calculated. Then, the residents are categorised into 10 groups according to their per capita income. The impact of the COVID-19 pandemic on income inequality could be revealed by comparing the changes in household per capita income by income group (Table 2 ) and examining the indicators for income inequality, such as the Gini coefficient and Lorenz curve (Figures 7-9) . While the COVID-19 pandemic would significantly reduce urban and rural residents' household per capita income, residents with lower income levels would suffer larger decreases in their per capita income. On average, the per capita income for the whole nation would fall by 7.87%. Rural residents would experience a more significant decrease in per capita income than urban residents, although the pandemic would cause greater damage to the earnings of urban labourers. This results from the fact that labour income accounts for a higher proportion of rural households' income. Compared with high-income residents, residents with lower income levels would suffer greater losses in per capita income. The per capita income of residents with the lowest 10% income would decline by 17.58% for the whole nation, 11.84% for urban residents, and 20.11% for rural residents. Comparably, the per capita disposable income of residents with the highest 10% income would decline by 4.78% for the whole nation, 4.81% for urban residents, and 5.70% for rural residents. This result can be explained by two factors. On the one hand, the COVID-19 pandemic would reduce the earnings of labourers with low education levels by a larger amount, and rural residents mostly had lower education levels than urban residents. On the other hand, labour income accounted for a larger proportion in the disposable income of the low-income households. By reducing the per capita income of low-income residents by a larger amount, especially for those living in rural areas, the COVID-19 pandemic would aggravate income inequality in China and threaten the living of poor residents. idents. This result can be explained by two factors. On the one hand, the COVID-19 pandemic would reduce the earnings of labourers with low education levels by a larger amount, and rural residents mostly had lower education levels than urban residents. On the other hand, labour income accounted for a larger proportion in the disposable income of the low-income households. By reducing the per capita income of low-income residents by a larger amount, especially for those living in rural areas, the COVID-19 pandemic would aggravate income inequality in China and threaten the living of poor residents. As indicated by Lorenz curves and Gini coefficients, the COVID-19 pandemic would aggravate income inequality in China. At the national level, the Gini coefficient would increase from 0.42 before the pandemic to 0.44 affected by the pandemic, accompanied by the Lorenz curve moving down and to the right (Figure 7) , which suggests that the COVID-19 pandemic aggravates income inequality in China. The aggravated income inequality of the nation is derived not only from the increased income gap between urban and rural residents but also the income inequality among urban or rural residents. Before the pandemic, urban and rural residents had Gini coefficients of 0.35 and 0.39, respectively, indicating a moderately greater income inequality for the rural residents. As shown in Figures 8 and 9 , influenced by the COVID-19 pandemic, the Gini coefficients of urban and rural residents would increase to 0.36 and 0.41, respectively, accompanied by the Lorenz curves moving down and to the right. Hence, for either urban or rural residents, the COVID-19 pandemic would aggravate income inequality among them. This is a result from the fact that the pandemic would reduce household per capita income by a greater amount for residents with a lower income. The impact of the COVID-19 pandemic is simulated on residents in poverty. The rate of poverty incidence is defined as the ratio of the number of the rural residents that have household per capita income below the poverty line to the number of rural residents. The rate of poverty incidence in China reached 0.60% in 2019 [58] . Although a household sample for 2020 is unavailable, it is still possible to simulate how the COVID-19 pandemic affects the rate of poverty incidence using the CHIP 2013 dataset. To do this, first, a threshold for the poverty line with the sub-samples of rural households is calculated by setting the poverty incidence rate at 0.60%. Then, calculate the number of rural residents with household per capita income below this simulated poverty line, which provides the poverty incidence rate during the pandemic. The results demonstrate that 2.11% of rural residents would have household per capita incomes below the poverty line due to the pandemic. This is also a result of the significant decreases in the per capita income of lowincome households. In other words, the pandemic would raise the poverty incidence rate by 1.51 percentage points. However, it is surprisingly observed that China's government had completely eradicated poverty in 2020, which is contrary to our simulation results. The inconsistency could be explained by the fact that the poverty alleviation policies implemented by China's governments are not considered after the pandemic outbreak [59] . The COVID-19 pandemic deeply affected China's macro-economy and labour market, consequently precipitating great shocks to household income. Gini coefficient Before the pandemic: 0.39 After the pandemic: 0.41 Figure 9 . Lorentz curve of rural residents before and after the COVID-19 pandemic. Source: Author's calculation. As indicated by Lorenz curves and Gini coefficients, the COVID-19 pandemic would aggravate income inequality in China. At the national level, the Gini coefficient would increase from 0.42 before the pandemic to 0.44 affected by the pandemic, accompanied by the Lorenz curve moving down and to the right (Figure 7) , which suggests that the COVID-19 pandemic aggravates income inequality in China. The aggravated income inequality of the nation is derived not only from the increased income gap between urban and rural residents but also the income inequality among urban or rural residents. Before the pandemic, urban and rural residents had Gini coefficients of 0.35 and 0.39, respectively, indicating a moderately greater income inequality for the rural residents. As shown in Figures 8 and 9 , influenced by the COVID-19 pandemic, the Gini coefficients of urban and rural residents would increase to 0.36 and 0.41, respectively, accompanied by the Lorenz curves moving down and to the right. Hence, for either urban or rural residents, the COVID-19 pandemic would aggravate income inequality among them. This is a result from the fact that the pandemic would reduce household per capita income by a greater amount for residents with a lower income. The impact of the COVID-19 pandemic is simulated on residents in poverty. The rate of poverty incidence is defined as the ratio of the number of the rural residents that have household per capita income below the poverty line to the number of rural residents. The rate of poverty incidence in China reached 0.60% in 2019 [58] . Although a household sample for 2020 is unavailable, it is still possible to simulate how the COVID-19 pandemic affects the rate of poverty incidence using the CHIP 2013 dataset. To do this, first, a threshold for the poverty line with the sub-samples of rural households is calculated by setting the poverty incidence rate at 0.60%. Then, calculate the number of rural residents with household per capita income below this simulated poverty line, which provides the poverty incidence rate during the pandemic. The results demonstrate that 2.11% of rural residents would have household per capita incomes below the poverty line due to the pandemic. This is also a result of the significant decreases in the per capita income of low-income households. In other words, the pandemic would raise the poverty incidence rate by 1.51 percentage points. However, it is surprisingly observed that China's government had completely eradicated poverty in 2020, which is contrary to our simulation results. The inconsistency could be explained by the fact that the poverty alleviation policies implemented by China's governments are not considered after the pandemic outbreak [59] . The COVID-19 pandemic deeply affected China's macro-economy and labour market, consequently precipitating great shocks to household income. Compared with wealthy households, low-income ones are more vulnerable to the pandemic, as the pandemic results in greater losses to their employment and labour earnings. However, the unequal impact of the COVID-19 pandemic on the labour market and household income in China are poorly tackled by previous studies. Combining a multisector CGE model (CHINAGEM) with a micro-simulation approach, this study develops an illustrative scenario to analyse the unequal impact of the COVID-19 pandemic on the labour market and household income in China. The study contributes to the literature from three perspectives. First, through incorporating a detailed labour matrix into the CHINAGEM model, the unequal impact of the COVID-19 pandemic on the employment and earnings of different labourer types are quantitatively assessed. Second, combining the CGE model with a micro-simulation approach, this study reveals the impact of the COVID-19 pandemic on the per capita income of households with different income levels. Third, to the best of our knowledge, this is the first study to examine how the COVID-19 pandemic affects income equality for rural and urban residents in China. The results show that: (1) the COVID-19 pandemic would cause significant damage to China's macro-economy by reducing China's national GDP and total employment by 3.77% and 6.72%, respectively. (2) The pandemic would have a far-reaching, heterogeneous impact on the employment and earnings of different labourer types. The labourers who are the female, live in urban areas, and have relatively low education levels would suffer the largest losses in employment and earnings. (3) Affected by the pandemic, per capita incomes would decline by 7.87% for the whole nation, 8.75% for rural households and 6.13% for urban households. While the pandemic would have a larger negative impact on the employment of urban labourers, it would have a greater negative impact on the per capita incomes of rural residents. (4) The per capita income of low-income households is more vulnerable to the pandemic than wealthy households. Per capita income of rural and urban households with the lowest 10% income would decline by 20.11% and 11.84%, respectively. (5) The COVID-19 pandemic would exacerbate income inequality for both rural and urban households and raise the poverty incidence rate by 1.51 percentage points. Overall, the COVID-19 pandemic would aggravate income inequality in China and threaten the living of the poor families, which should be treated with timely and powerful governmental policies. The results verify the research hypothesis that the COVID-19 pandemic would have an unequal impact on labour market and income inequality in China. In general, the simulation results of this study are fundamentally consistent with those of previous studies. First, for the economic losses, the previous studies projected that China's GDP in 2020 would decline by 2.71-5% [26, 45, 46] . This study simulated that China's GDP in 2020 would fall by 3.77%, which is within this range. Given the IMF's projection before the pandemic (6%), this study indicates that China's GDP would grow by 2.23% (=6% − 3.77%) in 2020, which is close to the official statistic (2.30% [4] ). Second, this study suggests that total employment would fall by 6.72%, which is close to the projection by Liu et al. [60] . They projected that total employment would decline by 5.96%. However, the reduction in total employment in this study is much higher than in Cui et al. [26] and Zhou et al. [56] , as they suggested that total employment would decline by 2.72% and 1.70%, respectively. This disparity could be explained by the fact that these studies employed early data to calculate the pandemic shocks, and consequently under-estimated economic losses. Third, this study found that labourers who are female, live in urban areas, and have low education levels would suffer greater losses in employment and earnings, which is consistent with the findings of previous research [10] [11] [12] [13] [14] [15] . Fourth, several studies suggested that the COVID-19 pandemic would have a greater negative impact on the per capita income of rural households, compared with their urban counterparts [16, 30, 36] . This study observed a similar phenomenon, but it initiatively gauged the changes in the income inequality of rural and urban households. Therefore, the results of this study are consistent with those of previous studies, but this study provides more insightful findings on the unequal impact of the COVID-19 pandemic on the labour market and income inequality. This study has several limitations. First, the data employed by this study were available in mid-2021, including the data of the 6th nationwide population census of China (surveyed in 2010), the Chinese Household Income Project (CHIP) database (surveyed in 2013), and the national input-output table of 2017. Thus, the data are somewhat outdated, considering the COVID-19 pandemic began in 2020. To alleviate the bias from the utilisation of these data, this study concentrates on the percentage changes in labourer employment and earnings as well as household income rather than their absolute values. Second, although households' total income collected by the CHIP survey contained the income earned from labourer employment, business activities, government transfers, and other sources, only labour income was reported separately. Hence, it is assumed that the nonlabour income of households remains unchanged under the impact of the COVID-19 pandemic. However, the pandemic caused significant damages to business activities, which have a larger negative effect on the income of wealthy households. This fact indicates that the change in income inequality may be overestimated owing to data unavailability. Furthermore, China's government enforced a series of timely and active policies for lowincome households to create jobs and increase their income through government transfers and targeted poverty alleviation programs. As a result, over 5.51 million populations got out of poverty in 2020. Hence, the simulation results of this study without considering governmental poverty alleviation policies may somewhat overestimate the distribution effects of the COVID-19 pandemic, but it could still provide a benchmark for future studies. This study puts forward three policies to mitigate the adverse impact of the COVID-19 pandemic on China's labour market and income inequality, which also provide important implications for other developing countries that are hit by the pandemic. First, to maintain labourer employment, more beneficial policies should be given to firms that suffer significant economic losses, particularly those engaged in the real estate, hotels, restaurants, and financial services sectors. To reduce production costs and ease shortages of funds for these firms, the government could extend the tax payment, reduce taxes, relax loan restrictions, and give them low-interest loans. Second, the government should identify the labourers most vulnerable to the COVID-19 pandemic, such as labourers who are the female, urban residents, and less-educated. Unemployed labourers should be given more supportive policies, such as the provision of professional training, living subsidies, and information on job opportunities to improve their labour skills and maintain their living. Moreover, the government could hire less-skilled, less-educated, and rural labourers who live below the poverty line in public service positions, such as street cleaners, river administrators, and road guards. Third, to continuously reduce income inequality, the government should not only improve social welfare policies, such as expanding the coverage of urban unemployment insurance to rural migrant workers, but also raise income transfers and reform the income redistribution mechanisms [61, 62] . China's government has implemented the policies related to the first two policy implications. Although the third implication has not resulted in specific policies, it should be considered strongly by the government to narrow the income gap and achieve the goal of common prosperity. Our research also provides important implications for other developing countries hit by the pandemic. Coronavirus: Limit Economic Damage Macroeconomic Implications of COVID-19: Can Negative Supply Shocks Cause Demand Shortages? Assessing the Impacts of COVID-19 on the Industrial Sectors and Economy of China Statistical Communique of the People's Republic of China on the 2020 National Economic and Social Development World Economic Outlook Database Impact of COVID-19 on Healthcare Labor Market in the United States: Lower Paid Workers Experienced Higher Vulnerability and Slower Recovery Rapid Review on COVID-19, Work-Related Aspects, and Age Differences Health, Economic, and Social Implications of COVID-19 for China's Rural Population The effectiveness of social distancing in containing COVID-19 Which Workers Bear the Burden of Social Distancing? The long downturn: The impact of the great lockdown on formal employment COVID-19: A Crisis of the Female Self-Employed Gender differentiated economic responses to crises in developing countries: Insights for COVID-19 recovery policies Explaining Gender Gaps in the South Korean Labor Market During the COVID-19 Pandemic Effects of the COVID-19 Recession on the US Labor Market: Occupation, Family, and Gender Unequal Pain: A Sketch of the Impact of the COVID-19 Pandemic on Migrants' Employment in China Who Loses Income During the COVID-19 Outbreak? Evidence from China Did the UK Policy Response to COVID-19 Protect Household Incomes? The Impact of COVID-19 on Households Income in the EU Distributional impact of COVID-19: Regional inequalities in cases and deaths in Spain during the first wave Migrant Workers and the COVID-19 Pandemic The Impact of Lockdown Policies on Labor Market Outcomes of the Chinese Labor Force in 2020: Evidence Based on an Employee Tracking Survey Labor Markets during the COVID-19 Crisis: A Preliminary View Global Supply Chains, and Local Labor Demand: Evidence from 100 Million Posted Jobs in China The Impact of COVID-19 on the Chinese Labor Market-A Comprehensive Analysis Based on the Individual Tracking Survey The impacts of COVID-19 pandemic on China's transport sectors based on the CGE model coupled with a decomposition analysis approach The impacts of the COVID-19 pandemic on employment in Cameroon: A general equilibrium analysis COVID-19 Employment Crisis in Vietnam: Global Issue Impact of COVID-19 on China's Macroeconomy and Agri-Food System-an Economy-Wide Multiplier Model Analysis. China Agric COVID-19 and Regional Income Inequality in China. Front. Public Health The Heterogeneous Effects of COVID-19 on Labor Markets: People's Movement and Non-Pharmaceutical Interventions Inequality in the Impact of the Coronavirus Shock: Evidence from Real Time Surveys Labour Market Dynamics in South Africa at the Onset of the COVID-19 Pandemic Who Suffers From the COVID-19 Shocks? Labor Market Heterogeneity and Welfare Consequences in Japan Economic Impacts of the COVID-19 Lockdown in a Remittance-Dependent Region Does the COVID-19 Pandemic Disproportionately Affect the Poor? Evidence from a Six-Country Survey The Distributional Consequences of Social Distancing on Poverty and Labour Income Inequality in Latin America and the Caribbean Impacts of the COVID-19 Pandemic on Rural Poverty and Policy Responses in China Minimum Wages and Household Poverty: General Equilibrium Macro-Micro Simulations for South Africa Will China's Demographic Transition Exacerbate its Income Inequality? A CGE Modeling with Top-Down Microsimulation Global Inequality in a more educated world Distributional impact of a regional road pricing scheme in Flanders Representative versus real households in the macroeconomic modeling of inequality Methods for including income distribution in global CGE models for long-term climate change research Impacts of COVID-19 on Global Poverty, Food security, and Diets: Insights from Global Model Scenario Analysis The Hit of the Novel Coronavirus Outbreak to China's Economy A Generic Single-Country Computable General Equilibrium Model Explaining a Dynamic CGE Simulation with a Trade-Focused Back-of-the-Envelope Analysis: The Effects of Ecommerce on Australia Economic and Climate Impacts of Reducing China's Renewable Electricity Curtailment: A Comparison between CGE Models with Alternative Nesting Structures of Electricity Employment Impacts of Renewable Energy Policies in China: A Decomposition Analysis Based on A CGE Modeling Framework Input-Output Table of 2017 Poverty and Inequality Analysis within a CGE Framework: A Comparative Analysis of the Representative Agent and Micro-simulation Approaches Income Distribution and CGE Micro-simulation Modelling: Does Individual Behaviour Matter? The Global Macroeconomic Impacts of COVID-19: Seven Scenarios The Aggregate and Structural Impacts of Public Health Event on Employment and Wage. Financ. Trade Econ COVID-19 and Its Macroeconomic Countermeasures in China: Impact and Effectiveness Chronic Diseases Associated with Increased Likelihood of Hospitalization and Mortality in 68,913 COVID-19 Confirmed Cases in Spain: A population-based cohort study Poverty Monitoring Report of Rural China Who Lost Most Wages and Household Income during the COVID-19 Pandemic in Poor Rural China? China World Econ Countermeasures against economic crisis from COVID-19 pandemic in China: An analysis of effectiveness and trade-offs Rural Vulnerability, Migration, and Relocation in Mountain Areas of Western China: An Overview of Key Issues and Policy Interventions. Chin Analyzing multidimensional measures of poverty and their influences in China's Qinba Mountains. Chin Source: The authors.Int. J. Environ. Res. Public Health 2022, 19, 1320