Abstract
The extant empirical studies do not wholly support the popular belief held by policy-makers on the positive influence of geographical proximity of incumbent exporters on the export decision of a non-exporter. To reconcile the mixed evidence, this paper examines the nonlinear relationship between the agglomeration of exporters and export decisions. In brief, the results show that the former positively affects the latter. Furthermore, the squared term of agglomeration calculated only by the number of skilled workers is negatively and significantly associated with export decisions, which can be explained by congestion costs in a local labor market for the skilled worker. As a result, these findings suggest an inverted U-shaped relationship between the agglomeration of exporters and the probability of being an exporter.
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Notes
The entry costs for exporting are related to gathering information on foreign consumers’ preference, establishing a distribution system in foreign countries, improving infrastructure necessary for distributing the products abroad, paying the search costs to identify local bankers, networking, adopting the product to new standards, and so on.
The mixed evidence may be attributed to the definition of the local export spillovers (restricted to multinational firms or including all exporters), the level of data disaggregation, and the different estimators used (Koening et al. 2010).
This paper employs the Levinsohn and Petrin (2003) method, which uses intermediate input, such as electricity, as the instrument variable in order to address the endogeneity problem. In order to estimate the production function, this study implements a STATA command (i.e., levpet) introduced by Petrin et al. (2004).
However, multiple plants have the same identification number. These plants are excluded as their percentage in the sample is only around 0.5 %.
Although Angrist and Pischke (2009, p. 196) dealt with peer effects in labor economics, the way to compute peer effects is the same as that for the agglomeration effect. Therefore, their suggestion is applied: “the best shot a causal investigation of peer effects focuses on variation in ex ante peer characteristics, that is, some measure of peer quality that predates the outcome variable and is therefore unaffected by common shocks.” Koenig (2009) and Bernard and Jensen (2004) also employed this approach to avoid the endogeneity problem.
A fixed effects (FE) model is preferable for its assumption that unobserved heterogeneity is random as well as the non-specification of its distribution. For the dynamic FE logit model, Honore and Kyriazidou (2000) proposed a semi-parametric estimator, which is, however, extremely data-demanding. Additionally, as the dynamic FE logit model does not assume the distribution of unobserved heterogeneity, the marginal effects cannot be computed to quantify the research interest (Wooldridge 2005). Thus, the dynamic FE logit estimator is not used.
Stewart’s (2006) STATA code is used, which suggests a shortcut implementation of Heckman’s estimator, i.e., rebprob. Despite Stewart’s shortcut implementation, the Heckman estimator still requires considerable computing time.
According to Stewart (2006), Wooldridge assumes normality of the conditional distribution of unobserved heterogeneity, given the initial observation of the dependent variable, whereas Heckman assumes bivariate normality for the unobserved heterogeneity and the initial observation of the dependent variable.
The Wooldridge’s method needs a set of covariates in order to use Mundlak’s suggestion. The set of covariates is constructed by using the logarithms of TFP, of plant size, of real wage per worker, and of agglomeration of exporting plants. However, the logarithms of real export subsidies and of foreign ownership are excluded due to the presence of zero values.
Heckman’s methods need a set of covariates in order to approximate the conditional density of initial observations, given a vector of the unobserved heterogeneity. The set of covariates is constructed by using the log of plant-level TFP.
This can be explained by the fact that exporting plants can pay higher wages to skilled workers than non-exporting plants can because of the higher productivity of exporting plants (Bernard and Jensen 1999; Kandilov 2009). In particular, exporting plants can pay their skilled workers a higher wage to prevent them from moving to a local competitor, i.e., a non-exporting plant. This is similar to foreign affiliates behavior (Fosfuri et al. 2001; Combes and Duranton 2006).
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Acknowledgments
I would like to give thanks to Robert McNown, Jin-Hyuk Kim, anonymous referee and the Editor Martin Andersson for valuable comments and suggestions. I am also grateful to Luis Castro for kindly sharing the Chilean plant-level data which comes from the Chilean National Statistics Institute (INE). This work was supported by the Soongsil University Research Fund of 2015.