Spatial global autocorrelation

To test for the presence of global spatial autocorrelation, Moran’s I test is used (Reference AnselinAnselin, 1988; Reference Nicolini, Resmini and KourtitNicolini and Resmini, 2011). This test detects the presence of spatial global autocorrelation, that is, if the gender gap in employment is distributed spatially at random or if, on the contrary, it presents spatial autocorrelation. The statistic to perform Moran’s I test is given as

$I=\frac{n}{\sum _{i=1}^n\sum _{j=1}^n{w}_{ij}}\frac{\sum _{i=1}^n\sum _{j=1}^n{w}_{ij}(y_i-\overline{y})(y_j-\overline{y})}{\sum _{i=1}^n{(y_i-\overline{y})}^2}$

where $y_{it}$ is the observation of the gender employment gap in municipality i, $\overline{y}$ is its mean and $w_{ij}$ are the spatial weights corresponding to municipalities i and j.

Depending on the type of contiguity between municipalities, there exist different specifications for the weights $w_{ij}$ . Following Reference AnselinAnselin (1988, Reference Anselin2002), two of the most common specifications are the queen method and the distance between the centroids of the municipalities. In the case of the queen specification, the weights take a value of 1 if the municipalities share a common edge or vertex and 0 otherwise. However, the weights of the second approach are obtained as the inverse of the distance between the centroids. The second criterion is in agreement with Tobler’s principle that regions closest in space are more similar than distant ones. We have chosen the latter approach based on this principle.

Figure 3 shows the values of Moran’s I statistic for each year of the period considered. As can be observed, Moran’s I is positive and statistically significant for all the years. The results confirm what was previously observed in Figure 2, that is, the municipalities of Andalusia display a high degree of spatial clustering over the 5-year period. That is, municipalities in close proximity to each other, have similar employment gap values.

Figure 3. Spatial autocorrelation (Moran’s I) for each year.

Source: Own elaboration based on data from Instituto de Estadística y Cartografía de Andalucía (IECA).

These results confirm H1 of our study, namely that the spatial distribution of the gender employment gap in Andalusian municipalities is not random, but formed by spatial clusters.

Models

In order to test H2 and H3, we estimated a spatial panel model. To this end, we first determined whether a pooled model, a fixed-effects (FE) model or a random-effects (RE) model was more suitable. The results of the Chow test (F = 15.912, p < 0.000) indicated that an FE specification was more suitable than a pooled specification. In addition, the results of the Breusch–Pagan test (χ² = 2707.4, p < 0.000) indicated that an RE model was preferable to a pooled model. Finally, the results of the Hausman test (Reference BaltagiBaltagi, 2005; Reference Elhorst, Fischer and GetisElhorst, 2009) indicated that an FE model was preferable to an RE model (χ² = 1165.6, p < 0.000). Hence, the FE model was the chosen specification.

We then determined whether the model perturbations presented problems of spatial autocorrelation. If the perturbations of the chosen model show spatial autocorrelation, an ordinary least squares (OLS) estimation will be unbiased, but not efficient and classical standard error estimators will be biased (Reference AnselinAnselin, 2001). To confirm the presence of spatial autocorrelation in perturbances, two Lagrange multiplier tests and their robust versions were used (LM-lag and LM-error and RLM-lag and RLM-error, respectively) (Reference Anselin and ReyAnselin and Rey, 1991), which would justify the use of spatial econometric methods. Table 2 shows the results of the tests, which indicate a strong presence of autocorrelation in the disturbances as they are highly significant. On the contrary, according to the likelihood ratio (LR) test (LR = 176.7856, p = 0.000), we can conclude that the SDM specification is appropriate.

Table 2. Estimated regression models for gender gap employment.

Source: Authors’ calculations.

FE: fixed effects; SDM: spatial Durbin model; LM: Lagrange multiplier; AIC: Akaike information criterion.

* Statistically significant at the p < 0.10 level; **statistically significant at the p < 0.05 level; and ***statistically significant at the p < 0.01 level.

The next step was to specify the spatial panel model. Although there are different spatial econometric panel models, SDM is one of the most attractive models for empirical spatial studies (Reference ElhorstElhorst, 2014) and can be used to test spatial interaction effects (Reference LeSage and PaceLeSage and Pace, 2009)

$y_{it}=\varphi +\rho \sum _{j=1}^N{w}_{ij}{y}_{it}+x_{it}\beta +\sum _{j=1}^N{w}_{ij}{x}_{ijt}\theta +u_{it}$

where $y_{it}$ is the dependent variable (gender_gap) for municipality i (i = 1…727) in period t (t = 1 … 5); $\varphi$ is the constant parameter; $\rho$ is the spatial autoregressive parameter which indicates the endogenous spillover effect of the gender employment gap; ${\sum }_{j=1}^N{w}_{ij}{y}_{it}$ is the spatial lagged dependent variable and represents the average gender gap in employment in neighbouring municipalities; $w_{ij}$ are the spatial weights; $x_{it}$ represents the explanatory variables; ${\sum }_{j=1}^N{w}_{ij}{x}_{ijt}$ denotes the values of the explanatory variables for the neighbouring municipalities; $\beta$ and $\theta$ are the associated parameters; and $u_{it}$ is the error. To control the endogeneity of the spatially lagged dependent variable, the maximum likelihood (ML) estimator was used (Reference AnselinAnselin, 1988).

The SDM captures not only the spatial endogenous spillover effect caused by the employment gap, but also the spatial spillover effect of the explanatory variables (Reference Gong, Boelhouwer and de HaanGong, Boelhouwer, and de Haan, 2014). Table 2 shows that the SDM coefficients of the key variables (unemploymen, mix, servicesector, dependency_rate and youngwomen) of our analysis are significant. Moreover, the coefficient of Wy (W*gender gap) is positive and significant. This indicates that the gender employment gap of municipalities tends to be affected by their neighbouring municipalities after accounting for the other explanatory variables, thus fulfilling H2. This endogenous spillover effect is likely due to the spatial diffusion mechanisms described in the literature review, namely that decisions taken by regional administrations to reduce the gender employment gap are affected by decisions taken by administrations in neighbouring regions.

Classically, the coefficients of panel models only consider direct effects but not spillover effect or indirect effects. In order to test H3, we follow the analyses of Reference ElhorstElhorst (2010) and Reference LeSage and PaceLeSage and Pace (2009), which consider the direct, indirect and total effects. The direct effects capture the impact of the change in the explanatory variables on the dependent variable, in a given municipality, while the indirect effects capture the impact of the change in the explanatory variables on the dependent variable in the neighbouring municipalities. These impacts are the result of spatial feedback (Reference LeSage and PaceLeSage and Pace, 2009). The sum of the two effects indicates the total effect of a change in the dependent variable. Table 3 shows the estimates of the three types of effects described. Therefore, to test H3 we look at the direct effects of the variables unemploywomen, unemploymen, mix, dependency_rate, youngwomen and pensionwomen, all of which capture factors related to the employment opportunity structure and certain socioeconomic characteristics of a municipality that affect the gender employment gap in that municipality. As can be observed in the table, the indirect effects of the variables unemploymen, mix, servicesector, dependency_rate, youngwomen, pensionmen and income are significant. This indicates that factors related to a municipality’s labour and socioeconomic characteristics also affect the gender employment gap in neighbouring municipalities.

Table 3. Direct, indirect, and total effects.

Source: Authors’ calculations.

* Statistically significant at the p < 0.10 level

^** statistically significant at the p < 0.05 level

^*** statistically significant at the p < 0.01 level.

To interpret the results of Table 3, we have selected the variable dependency_rate. This variable has a direct positive and significant effect on the gender employment gap. This finding indicates that municipalities with a high proportion of underage children and elderly individuals have a higher percentage of gender gaps. Thus, if the variable dependency_rate increases by 1% in a municipality, the gender employment gap will increase by 0.27% in that municipality. Moreover, the indirect effect is also positive and significant, indicating that if the variable dependency_rate increases by 1% in one municipality, the gender employment gap in neighbouring municipalities will increase by 0.12%. As indicated above, the indirect effect represents the spatial spillover effect of the explanatory variables (Reference Gong, Boelhouwer and de HaanGong et al., 2014). Hence, it can be concluded that this variable shows significant spatial spillover. The sum of the two effects (direct and indirect) indicates that if the proportion of underage children and the elderly increases by 1%, the total effect on the gender gap will be an increase of 0.39%. The results obtained for the rest of the significant variables are the expected ones in line with the literature review (Reference ManskiManski, 1993; Reference Voss, Long and HammerVoss et al., 2006). The importance of distinguishing between direct and indirect effects is evidenced by the spatial spillover effects of certain explanatory variables (indirect effects) which, in our case, highlight the need to account for certain regional characteristics when analysing the gender employment gap.