Currently, no consensus has emerged in the academic community regarding the impact of digital economy development on the urban–rural income gap. As briefly described above, the research conclusions can be roughly divided into three categories.

• (1)

  Research on the expanding effect of the digital economy on the urban–rural income gap. Furuholt and Kristiansen (2007) emphasized that the digital economy, which is characterized by the internet, big data, artificial intelligence, and other forms, may result in imbalanced development between urban and rural areas, resulting in a digital divide (Lorence et al., 2006), which is unfavorable for low–income rural populations (Gorski & Clark, 2002). Tan et al. (2017) argued that a gap is evident between urban and rural residents in digital economy acceptance and application. Rural residents have limited resources, education, and business environments than urban residents (He & Xu, 2019). Furthermore, rural residents cannot identify and use information effectively or fully enjoy the advantages of internet diffusion (Lv, 2021). In contrast, urban residents are in a position of information advantage and can more conveniently access and use digital information through the internet. Furthermore, urban residents’ digital awareness and capabilities are continuously enhanced, which ultimately widens urban–rural wealth disparities, particularly income (Li & Ke, 2021). This viewpoint highlights the possibility that the digital economy may widen the income gap between urban and rural areas, reminding policymakers to pay attention to the potential inequality issues. However, this viewpoint may be too pessimistic and may overlook some of the positive impacts of the digital economy.

• (2)

  Research on the reduction effect of digital economy on the urban–rural income gap. This perspective argues that digital economy development contributes to narrowing the urban–rural income gap. Some scholars have demonstrated that the digital economy can increase farmers’ income and narrow the urban–rural income gap (Bhavnani et al., 2008; Aker & Dial, 2011). Acemoglu and Restrepo (2016) proposed that digital technologies such as the internet break down spatiotemporal barriers, providing laborers with more employment choices and enhancing market resource allocation efficiency. Liu et al. (2021) argued that digital economy development has facilitated significant achievements worldwide, improving impoverished population's living conditions. Moreover, the digital economy has been found to directly reduce the urban–rural income gap (Liu, 2021). Digital economy development can leverage inclusiveness and resource sharing through deep integration of production, life, and ecology (Fu, 2020). The digital economy functions as an endogenous driving force that overcomes geographical constraints, eliminates information barriers, expands employment opportunities, and advances growth in underdeveloped regions. It also drives optimized factor allocation, promotes the division of labor and collaboration, improves labor productivity, enhances economies of scale, and facilitates coordinated regional development (Duan et al., 2020; Hu et al., 2017; Song, 2012). This viewpoint emphasizes that the digital economy may provide opportunities for narrowing the urban–rural income gap and a possible way to achieve income balance. It can motivate governments and enterprises to increase their investment in related fields and promote the coordinated development of urban and rural economies. However, this viewpoint may be too idealistic, ignoring the new inequality issues that the development of the digital economy may bring; it may also overlook the complex and diverse impact of the digital economy on different regions and populations, which may not directly lead to the narrowing of the urban–rural income gap.

• (3)

  Research on the nonlinear effect of the digital economy on the urban–rural income gap. A nonlinear relationship exists between digital economy development and the urban–rural income gap. Ashraf et al.( 2021) argued that as information and communications technology (ICT) is promoted and adopted, income inequality decreases over time. Jiang et al. (2022) revealed a U-shaped relationship between the digital economy and the urban–rural income gap, with the gap narrowing in early stages and widening in later stages. Zheng and Li (2022) proposed that the impact of digital economy on the urban–rural income gap can have simultaneous expanding and narrowing effects, and the overall impact depends on the relative magnitude of these effects. Considering that the digital economy and the urban–rural digital divide are in a continuous dynamic development process, their relationship is likely to exhibit time–varying characteristics, exhibiting a complex nonlinear relationship. Wang and Xiao (2021) found that the development of the digital economy has a U-shaped relationship with the urban–rural income gap, initially narrowing and then widening. A similar perspective was presented by Chen and Wu (2021), who proposed that while the initial stages of digital economy development can promote urbanization and narrow the urban–rural income gap, further development and the resulting digital divide negatively impact rural surplus labor migrating to cities for employment, widening the urban–rural income gap. Conversely, Li and Li (2022a), and Cheng and Zhang (2019) opined that the impact of digital economy on the urban–rural income gap shows an overall inverted U-shaped trend, with an initial increase and subsequent decrease. They proposed that in the initial stage of digital economy development, due to the disparity in human capital and the existence of the digital divide between urban and rural areas, rural residents cannot fully utilize digital economy resources to increase their income compared to urban residents, resulting in an expanding urban–rural income gap. However, later on, due to the law of diminishing marginal utility, the marginal impact of urban digital economy development on income will gradually be surpassed by rural “latecomers”, leading to a narrowing of the urban–rural income gap. Supporting this view, Li and Li (2022b) argued that the impact of digital economy development on the urban–rural income gap follows an inverted U-shaped pattern, and a threshold effect exists in the relationship between digital economy development and the urban–rural income gap. This view is closer to reality, recognizing that the impact of digital economy on urban and rural incomes is complex and varied, not single–linear, and may show different stages of changing trends. However, grasping the specific pattern of nonlinear relationships accurately is difficult, and more empirical research and data support are required.

The divergent findings of the aforementioned studies can be attributed to three main reasons. First, the impact of digital economy development on the urban–rural income gap exhibits spatial heterogeneity, while existing research models often assume a mean regression, assuming that the impact coefficients are the same for all regions. For example, Wang and Xiao (2021) studied 30 provinces in China from 2013 to 2019 and found that the impact of digital economy development on narrowing the urban–rural income gap was mainly concentrated in the central and western regions, with a slight widening effect in the eastern region and unclear effects in the northeastern region. Second, traditional econometric models assume that research subjects are independently and identically distributed, but the levels of digital economy development and the urban–rural income gap in different regions may exhibit spatial spillover effects, violating this assumption. The development of the digital economy and the urban–rural income gap in each province, city, and autonomous region is not only influenced by local factors but also interacts with the development of the digital economy or the urban–rural income gap in neighboring regions. Several studies have demonstrated spatial autocorrelation (Si & Li, 2023; Wei & Chen, 2020), indicating the need to use spatial econometric models instead of traditional regression models. Third, most studies only consider the direct impact of digital economy development on the urban–rural income gap, with less consideration of its indirect effects; even fewer studies involve the spatial heterogeneity of these indirect effects. If the directions of the direct and indirect effects are opposite, the overall effect after aggregation is uncertain.

In summary, a comprehensive understanding of the impact of digital economy development on the urban–rural income gap requires simultaneous consideration of spatial correlation, spatial heterogeneity, and direct and indirect effects. However, limited studies have taken this approach. Therefore, this study proposes the following hypothesis:

• H1. The influence of the digital economy on the income gap between urban and rural areas is spatially heterogeneous, and the influence in different regions has expanding, narrowing, or uncertain relationships.

The spatial weight matrix is not only the biggest difference between spatial econometric models and traditional mean reversion models but also a key factor in geographically weighted regression and its extension models. In both models, spatial weights are used to represent the interdependence between individuals or regions, which requires a uniform spatial weight setting.

Unlike previous spatial weight settings, this study draws on the concept of gravitational potential to construct an asymmetric spatial weight matrix that incorporates geographical and economic distances. Potential gravitational energy (F=Gmi·mjdij) is used to express the mutual gravitational force between two objects, where F is the value of the potential gravitational energy between the two objects, G is a gravitational constant value of 6.67×10−11Nm2/kg2, mi and mj denote the masses of objects i and j, respectively, and dij is the distance between the central mass of the two objects. If the numerator is replaced by an economic total of the two regions, it combines economic and geographical distance. Using this approach to construct a spatial weight matrix is more accurate than only using economic or geographical distances. However, the spatial weight matrix is symmetric, and the mutual influence between the two regions is the same, which obviously does not conform to reality. In reality, the impact of regions with large economic output on regions with small economic output is greater than that of regions with small economic output on regions with large economic output. Therefore, we reference Newey and Powell (1987), constructing asymmetric least-squares estimators, rewriting the potential gravitational energy formula, and establishing an asymmetric spatial weight. The specific forms are as follows:

Verifying the superiority of the asymmetric potential gravitational energy spatial weight proposed in this study requires comparison with traditional spatial weights constructed based on the reciprocal of economic distance (1/|mi−mj|) and geographical distance (1/dij). Table 1 estimates the values of the Akaike information criterion (AIC) and Bayesian information criterion (BIC) corresponding to the three weights based on the direct effects model in Eq. (2). The results reveal that the AIC and BIC values of the asymmetric potential gravitational energy spatial weight are the smallest, indicating that they are superior to the traditional spatial weight matrix constructed based on geographic and economic distances.

According to the MGWPR–SDM, we construct the following global smooth SDM:

Previous research has demonstrated that human capital exerts a decisive influence on upgrading industrial structure (Romalis, 2004; Hausmann et al., 2007). Chen and Yang (2014) determined that human capital significantly contributes to upgrading China's industrial structure. Additionally, regional differences are evident concerning the impact of human capital heterogeneity on industrial structure upgrading. High skilled human capital significantly promotes the upgrading of industrial structure in the eastern region, while its promotion effect is not significant in the western region (Zhang et al., 2011). To further analyze the impact mechanism of the digital economy on the urban–rural income gap, we reference Yu and Zhu (2023) constructing a chain-mediating effect model.

Fig. 1 shows that the indirect impact of digital economy development (Digi) on the urban–rural income gap (Gap) has three paths. (1) Digi has an impact on the Gap by affecting human capital (Hc), with an effect size of β1*α2. (2) Digi affects the Gap by influencing the industrial structure (Stru), with an effect size of γ1*α3. (3) Digi has an impact on the Stru by influencing Hc, which affects the Gap, with a magnitude of β1*γ2*α3.

Fig. 1.

Diagram of the chain mediating effect model.

(0.04MB).

Table 3 presents the statistical indicators, including minimum value, interquartile, median, mean, interquartile, maximum value, and standard deviation of variables. The minimum value of Gap is 1.840 and the maximum value is 3.800, indicating significant differences in Gap across China's regions. The minimum value Digi is 0.015 and the maximum value is 0.509, which also indicates a digital divide in digital economy development in various regions of China.

Data related to e–commerce have only been available since 2013 and do not include data from Hong Kong, Macao, Taiwan, and Xizang. Therefore, this study uses panel data from 30 provinces in China from 2013 to 2021 for empirical analysis. The data are sourced from the “China Population and Employment Statistical Yearbook” from 2014 to 2022, the official website of the National Bureau of Statistics, and the “Peking University Digital Inclusive Finance Index Report” published by the Peking University Digital Finance Research Center.

We first determine whether a spatial econometric model is required. Moran's Index (Moran's I) is an important indicator for measuring spatial correlation, and uses the Moran's I statistic to test whether sample individuals are spatially independent of one another. The Moran's I test results in Table 4 that when Gap, Hc, and Stru are used as explanatory variables, the p-values corresponding to the Moran's I statistic are all 0.000, which significantly rejects the null hypothesis that the variables do not have spatial correlation at the 5 % level. All three variables have significant spatial autocorrelation; therefore, a spatial lag term should be added to the model as an explanatory variable, employing a spatial econometric model.

Second, spatial econometric models have various forms such as the spatial autoregression (SAR), the spatial error model (SEM), and the SDM. Model selection requires appropriate testing. This study uses the likelihood ratio approach to test whether the SDM degenerates into SAR or SEM, and Table 5 summarizes the results. The p-values corresponding to the chi-square statistics of Models (1)– (3) are all less than 5 %, indicating that all three models reject the original assumption that SAR and SEM models are true; therefore, the SDM with bidirectional fixed effects should be chosen.

As some variable coefficients may occur in Models (1)– (3), it is necessary to identify the coefficients that change with spatial variation through testing. Regarding the variable selection problem in the mixed geographic weighted regression model, Mei et al. (2016) proposed applying a bootstrap method for variable coefficient selection, which is more robust than the F-test proposed by Brunsdon et al. (1999). Table 6 presents the test results obtained using this method.

Combining the results of variable selection in Table 6 and compared with the model in Equation (11) from Yu et al. (2021) reveals that Models (1) and (2) have some explanatory variables with insignificant bootstrap tests, and the corresponding p-values are more significant than 0.05, indicating that they are fixed coefficients and the other explanatory variables are variable coefficients. This confirms suitability for employing the MGWPR–SDM because the spatial lag term WY of the explanatory variables in Model (1) is a variable coefficient, and suitable for applying the MGWPR–SDM (1, kc, kv), while the spatial lag term WY of the explanatory variables in Model (2) is a fixed coefficient, which is suitable for applying the MGWPR–SDM (0, kc, kv). Similarly, the p-values corresponding to the explanatory variables in Model (3) are less than 0.05, indicating that all the explanatory variables, including WY, are variable coefficients; therefore, the MGWPR–SDM (0, 0, kv) is applicable.

As this study focuses on the core explanatory variable Digi and the mediating variables of Hc and Stru, we do not interpret the remaining control variables. Table 7 reveals that only Stru in Model (1) has a fixed coefficient that is statistically significantly positive at the 1 % level, suggesting that upgrading the Stru will widen the Gap, and its impact varies less across regions. The Stru of neighboring regions (w_Stru) in Model (1) and the core explanatory variable Digi, the mediating variable Hc, and Stru in the other two models are variable coefficients (Table 7).

Table 8 presents the mediation results for Model (1), revealing that the coefficients of Digi are both positive and negative, with a maximum value of 0.094 and a minimum value of −0.145, indicating that digital economy development widens the Gap in some regions, while the opposite is true for other regions. Similarly, the coefficients of Hc are both positive and negative, suggesting that the enhancement of human capital in some regions reduces the Gap, while the opposite is true for other regions.

Table 9 presents the results of mediation Model (2), revealing that the coefficients of Digi are both positive and negative, with a maximum value of 1.698 and a minimum value of −1.196, indicating that digital economy development in some regions enhances human capital, while the opposite is true for other regions. Furthermore, digital economy development in the neighboring regions (w_Digi) also exhibits both a positive and negative impact on the region's human capital, revealing that some neighboring regions can promote human capital improvement, whereas others have the opposite effect.

Table 10 presents the mediation results for Model (3), revealing that the coefficients of Digi are both positive and negative, with a maximum value of 0.130 and a minimum value of −0.303. This indicates that digital economy development in some regions can promote the Stru integration and upgrading and the opposite occurs in other regions. Furthermore, the impact of the digital economy development in neighboring regions (w_Digi) on Stru is positive and negative. Digi in neighboring regions (w_Digi) has positive and negative effects on the local Stru; that is, some neighboring regions promote local Stru upgrading, whereas others have the opposite effect. The coefficient of Hc is both positive and negative, with a maximum value of 0.058 and a minimum value of −0.055, indicating that enhancing human capital in some regions promotes Stru integration and upgrading, while the opposite is true in other regions. The influence of Hc in neighboring regions (w_Hc) on Stru upgrading is also both positive and negative; that is, some neighboring regions promote Stru upgrading, while others do not.

To clearly illustrate the spatial heterogeneity of the mechanism of impact of Digi on Gap, this study presents each mediating effect in the form of maps. The left sides of Figs. 2–4 present the effect values and the right sides show the p-values corresponding to the Sobel (1982) test.

Fig. 2.

Mediating effect and statistical significance of path 1.

(0.26MB).

Fig. 3.

Mediating effect and statistical significance of path 2.

(0.25MB).

Fig. 4.

Chain mediating effect and statistical significance of path 3.

(0.26MB).

Fig. 2 reveals significant spatial heterogeneity in Digi’s effect on Gap through Pathway 1. The coefficients of Jilin, Inner Mongolia, Shanxi, Hubei, Guangdong, and other regions are positive at a 10 % significance level, indicating that Digi widens the Gap by enhancing Hc. The coefficients of Fujian, Chongqing, and other regions are negative, indicating that Digi can effectively narrow the Gap by enhancing Hc. Most regions in central China are positive, and northwestern regions and Heilongjiang and Liaoning are negative, but none of them are significant.

Fig. 3 reveals that Pathway 2 also exhibits significant spatial heterogeneity. The coefficients in most regions of east, central–west, and northeast China are negative at a 10 % significance level, with Jiangxi and Hubei having the largest effects. This indicates that Digi has narrowed the Gap in these regions by upgrading the industrial structure. In contrast, Beijing, Shanxi, Ningxia, Inner Mongolia, and other regions exhibit positive coefficients, indicating that Digi has widened the Gap in these areas by upgrading the industrial structure.

Fig. 4 illustrates the magnitude and significance of the chain-mediated effects, indicating that Digi influences the Gap by altering Hc, which subsequently affects Stru. The coefficients in regions such as Jilin, Tianjin, Hubei, and Guangxi are positive at the 10 % significance level, whereas regions such as Shanxi, Inner Mongolia, Henan, and Fujian exhibit negative coefficients. The coefficients in other regions have both positive and negative values, but are not statistically significant.

In addition to examining the indirect effects mediating variables such as Hc and Stru on the Gap through, Digi also directly impacts the Gap. Fig. 5 presents the direct effects and their significance, revealing that the Digi in Jiangxi, Chongqing, and Shaanxi has significantly widened the urban–rural income gap. In contrast, the Digi in Jilin, Shandong, Zhejiang, Yunnan, Hebei, Sichuan, Guizhou, Liaoning, Hainan, and Xinjiang significantly narrowed the Gap. Digi had no significant impact on the Gap in other areas.

Fig. 5.

Direct effect and statistical significance of digital economy on the urban–rural income gap.

(0.25MB).

The analysis above reveals that the three indirect pathways through which Digi affects the Gap exhibit significant spatial heterogeneity, with both positive and negative effects. These effects tend to offset each other, making it necessary to investigate the weight of the three mediating effects to examine overall indirect impact.

Fig. 6 presents the weights of the indirect and total effects. The left graph in Fig. 6 shows that the total mediating effect of Digi on the Gap is negative in most regions. Only 12 provinces and cities exhibit a positive total mediating effect, and Jilin Province in the northeast had the largest effect, followed by Beijing, Inner Mongolia, and Shanxi in north China; Henan, Hubei, and Jiangxi in the central region; and Shandong, Jiangsu, Guangdong, and Hainan in the east coast area, with relatively smaller effects. The graph on the right of Fig. 6 presents the spatial distribution of the total effects after combining the total and direct mediating effects. Notably, the impact of Digi on the Gap varies across regions, with some regions exhibiting a reduction in the income gap, while others show an expansion. Additionally, the spatial distribution of the total effects closely resembles the total mediating effects on the left graph, indicating that the total mediating effects are significantly larger than the direct effects.

Fig. 6.

Total indirect effect and total effect of the digital economy on the urban–rural income gap.

(0.26MB).

This study constructs a digital economy development index to measure the Digi of 30 provinces and cities in China from 2013 to 2021. Embedding the MGWPR–SDM into a chain–mediated effect model and considering spatial autocorrelation and spatial heterogeneity, we analyze the mechanism of Digi’s impact on the Gap and its spatial heterogeneity. The results demonstrate that Digi can affect the Gap through one direct path and three indirect paths, all of which exhibit obvious spatial heterogeneity. The effects of each path cancel each other out, resulting in the same spatial heterogeneity for Digi’s total effect on the Gap. For example, Digi in areas such as Jilin, Inner Mongolia, and Shanxi widened the Gap, while Digi in areas such as Chongqing and Zhejiang narrowed the Gap.

Regarding the mechanism of Digi’s impact on the Gap, Digi widens the Gap in most regions by upgrading human capital, with the largest effect in Jilin Province in Northeast China, followed by Inner Mongolia and Shanxi in North China, and a relatively small effect in most provinces in Central and East China (Fig. 2). Furthermore, Digi narrows the Gap in the vast majority of regions by promoting the upgrading of industrial structure. Among them, Hubei and Jiangxi provinces in the central region had the largest effect, followed by central, southern, northeastern, and northwestern China; only Beijing, Inner Mongolia, and Shanxi in northern China and Ningxia in northwestern China had a positive path 2 effect (Fig. 3). Digi affects the Gap by upgrading human capital and thus promoting industrial structure upgrading (i.e., the chain mediation effect) in the eastern region of Tianjin, Hebei, Shandong, Jiangsu, Zhejiang, Anhui, and Hunan in the central region, Ningxia, and Shaanxi in the western region, and most of the southwestern region is positive, indicating that Digi widens the Gap through Path 3, while other regions narrow the Gap through Path 3 (Fig. 4). Additionally, Digi’s direct impact reduces the Gap in most regions (Fig. 5). Combining the above four paths shows that there is also significant spatial heterogeneity in the total impact of Digi on the Gap. Digi in Beijing, Inner Mongolia, Shanxi, Henan, Hubei, Jiangxi, Jiangsu, Guangdong, and other provinces has widened the Gap, resulting in a digital divide effect. However, in most areas of the Northeast, eastern coastal regions, and western regions, Digi has narrowed the Gap, resulting in a digital dividend effect (Fig. 6).

Based on these findings, this study presents the following policy implications. First, interregional cooperation and coordination must be strengthened. Due to the spatial autocorrelation of the Gap, local governments should collaborate to address the associated externalities rather than developing policies independently. This means that local governments should collaborate with neighboring regions and other local governments to jointly develop policies that can coordinate income disparities between different areas. Second, some regions—especially Fujian and Chongqing—should increase efforts to enhance Hc. It is possible to consider integrating digital education resources, remote vocational training, digital talent matching platforms, data–driven talent cultivation, and digital innovation and entrepreneurship support to fully leverage digital economy dividends, effectively improve rural labor's Hc, promote rural economic development, and narrow the Gap. We also focus on the integrating and upgrading Stru. Hubei and Jiangxi provinces in the central region and local governments in central, southern, northeastern, and northwestern regions can promote Stru upgrading and transformation by advancing digital agricultural technology, digital industry upgrading, and digital service industry development. This will improve rural employment opportunities and incomes, promote sustainable development of the regional economy, achieve integrated development of urban and rural economies, and balance the growth of society by narrowing the Gap. Additionally, policies should be strategically tailored to local conditions. Each region should develop corresponding policies based on its socioeconomic conditions and natural resource endowments, reasonably develop the digital economy, and narrow the Gap in a context–specific manner. Regional disparities must be considered, and policies must be targeted and feasible to achieve the optimal results.