3.1 Data on migration policy selectivity

Ideally, information on migration policy selectivity would be structured and made available according to entry tracks, which – as defined in the IMPALA project – are the specific ways of entering a country, distinguished by the purpose of migration and the characteristics of migrants (see Beine, Burgoon, et al., Reference Beine, Burgoon, Crock, Gest, Hiscox, McGovern, Rapoport and Thielemann2015, p. 9). These would allow a straightforward derivation of the extent to which the restrictiveness of migration policy depends on specific migrant characteristics. However, databases organized in this way are still under construction. Available data that comes closest to this format is the DEMIG database (see also DEMIG, 2015). The dataset contains a comprehensive list of all changes to migration policy and identifies which migrant group was affected and to what extent for each change. As such, DEMIG serves as the primary source of data for this study.

The DEMIG project registered and coded 6,500 migration policy changes enacted since the 18th Century, most of which were between 1945 and 2013. It does this for 45 (destination) countries, forming the largest change-tracking database completed to date (see de Haas et al., Reference de Haas, Natter and Vezzoli2015). For each measure, this database lists the country and year of application, level of legislation (national policy or international agreement), policy area (border control, legal entry, integration, exit), policy tool (e.g., recruitment agreements, work permit, expulsion, quota, regularization), targeted origin countries (e.g., all foreign nationalities, EU citizens, specific nationalities), targeted migrant groups (e.g., low and high-skilled workers, family members, refugees, irregular migrants, students) and an assessment of how much it impacts the restrictiveness of the existing legal framework (magnitude of the change) on a four-point scale (for more information, see the DEMIG Policy codebook).

The target group variable distinguishes between 15 categories, of which three are relevant according to our definition of selectivity: (i) measures conditional upon the skill level of the migrant (low and high-skilled),Footnote ⁹ (ii) measures applicable to “investors, entrepreneurs and businesspeople”, i.e., the economically well-endowed,Footnote ¹⁰ and (iii) measures targeting migrants of specific nationalities (for instance through bilateral agreements or aimed at EU citizens).Footnote ¹¹

While the DEMIG database offers a detailed comparison of the changes in migration policies for a large group of countries, several relevant changes are not included. We complement DEMIG with information from several additional sources to fill in the gaps. First, we rely on the Bilateral Labor Agreement (BLA) dataset compiled by Chilton and Posner (Reference Chilton and Posner2018), which provides additional information on selectivity in terms of nationality. The authors compiled a list of bilateral labor treaties since the Second World War by bringing together information from the United Nations Treaty Series, the World Treaty Index, the website of the International Labour Organisation, foreign ministry databases and internet searches for academic articles. For each treaty, they list the year it was signed and the countries that signed it.

Second, we use and extend the work of Xu et al. (Reference Xu, El-Ashram and Gold2015) and Džankić (Reference Džankić2015), who collected information on immigrant investment programs (IIP) and economic citizenship programs (ECP) – the so-called “golden visas”. These are programs where countries offer migrants facilitated access to residence rights or citizenship in exchange for a (substantial) financial contribution. Our data come from both official country websites and from business (solicitor offices) websites.Footnote ¹² For each IIP and ECP, we registered the minimal amount that was required to obtain either a residence permit or citizenship, as well as the year of application or modification. The earliest information on these schemes goes back to the 1990s. Whereas initially, only a few Anglo-Saxon countries had such programs in place, IIP and ECP became popular after the financial crisis of 2007 in many (mostly small) countries like Greece, Portugal and Slovenia. As they offer easier access conditional upon financial investment, IIP and ECP are informative on selectivity in terms of economic resources.Footnote ¹³

For each change in migration policy, DEMIG provides information on the direction of the change and its magnitude. I.e., whether the policy restricts or enables migrant flows and how much it impacts the restrictiveness of the existing legal system. In contrast, the BLA and (extended) IIP/ECP databases only provide dichotomous information indicating the existence of an agreement/program and – for the latter – also the required minimal financial contribution. To integrate them into the DEMIG database, we need to add an assessment of the magnitude of the change in restrictiveness stemming from these BLA and IIP/ECP. To do that, we used the partial overlap between the databases, i.e., the BLA and IIP/ECP that already appeared in DEMIG. Conveniently, they were all assigned identical scores, i.e., within the same policy area, with the same direction and order of magnitude. Therefore, we could assign identical scores to those BLA and IIP/ECP not yet included in the DEMIG database.

3.2 Indexes of migration policy selectivity

The combination of DEMIG with the BLA and IIP/ECP information provides a rich and comprehensive database, listing the legislative changes to migration policy in 42 countries since the end of the Second World War. For each legislative change, it lists the destination and origin countries, the year, the direction and magnitude, and the targeted migrant group.

However, in its raw format, the database does not allow us to compare the selectivity of the migration policies over time or between different countries. To enable this comparison, we construct indexes that express the extent to which a country's migration policy provides preferential access to certain migrants based on several specific characteristics. Specifically, we create indexes that track (i) how the skill and resource-based selectivity of each of the destination countries’ migration policy changes over time; (ii) how the level of restrictiveness of migration policy for each origin-destination country pair changes over time; and (iii) how – based on (ii) – selective each destination country's migration policy is in terms of nationality globally, i.e., for all origin countries included. We consider all measures that had a differential impact based on nationality, skill, or economic resources, regardless of the channel of entry that they affect.Footnote ¹⁴ Figure 1 provides an overview of the entire data processing algorithm.

Figure 1. Overview of the algorithm used to create the selectivity indexes.

First, we select from the database all selective legislative changes and categorize them according to the basis for selectivity: migrants’ skills, resources or nationality. Each measure that qualifies subsequently receives a score based on the direction and magnitude of the change. For skill-selective measures, a positive score is given to measures that ease access for high-skilled workers or restrict access for low-skilled workers, and a negative score otherwise.Footnote ¹⁵

Similarly, for resource-selective measures, a positive score is attributed to measures that eased the access of investors, entrepreneurs or the well-endowed. For nationality-selective measures, we track whether the access is eased (positive) or restricted (negative) for each origin country. For example, if a country joined the Schengen area, this was coded as a positive change toward all other members of the Schengen area. As the group of Schengen countries changed over time, the change in access for the newly joined members was also updated.

The next step in creating the indexes involves rearranging a dataset based on individual laws to one aggregated at the country-time level. We conjecture that the newly constructed database contains all relevant policy changes so we can attribute a score of zero to years without legislative changes. On the other hand, if multiple legislative changes took place within the same year, we take the sum of their scores. For skill and resource selectivity, this gives us the yearly change in selectivity in each destination country. For nationality-based selectivity, we end up with a dataset that tracks the yearly change in restrictiveness for each origin-destination pair.

After this re-categorization, our dataset lists the yearly changes in the selectivity of destination countries’ migration policy. To get the yearly level of migration policy selectivity that can be compared across countries, we require at least one measurement comparing the (initial) level of these countries. Unfortunately, such data does not (yet) exist. However, we can reasonably approximate the yearly level of migration policy selectivity by looking at a long cumulative change (running sum) in migration policy selectivity. After summing up the yearly changes over a sufficiently large period, it is not unreasonable to assume that the initial level no longer determines the current level of restrictiveness. We take 1945 as our zero point since the end of the Second World War was a period of major political and institutional change. From that point forward, we use the cumulative sum of the scores by dimension and policy area and discard the first 45 years of our data (i.e., from 1945 to 1989) as burn-in. To be clear, we do not mean to imply that the policies before 1945 are unimportant. Rather, they no longer determine the level of selectivity in migration policy 45 years later. For example, our chosen starting point excludes the “White Australia Policy”, which forbade non-Europeans from settling in the country, as this policy dates back to 1901. However, by the mid-1970s, this policy had been entirely dismantled. The choice of start date would only completely distort our findings if a country had designed its migration policy entirely before 1945 and made no subsequent changes.Footnote ¹⁶

Importantly, our choice of zero-point does not have any implications for the empirical analysis of the effectiveness of the migration policy measures (as reported in Section 4). This is because these analyses include origin-destination fixed effects, which account for the initial level of selectivity.Footnote ¹⁷

The main drawback of using a running sum as a proxy of the selectivity level is that any errors in the dataset will be compounded. Measurement errors throughout the dataset imply that the results become less informative or trustworthy as we compute the running sum over a more extended period. As such, our indexes are contingent upon the dataset being (mostly) without errors. In Appendix A, we consider how the created indexes change when we instead allow the migration policies to fade out in the long run.

Our indexes of selectivity based on skills and resources, MPS ^skill and MPS ^res, are obtained after a normalization that sets their standard deviation equal to one. This results in a yearly score for the skill and resource selectivity indexes that can be compared across all 42 destination countries in our sample. The closer the score lies to zero, the more equal the incoming migrants are treated. It is important to note that the skill and resource selectivity indexes can take negative values, which would signal that people with low skills or few resources gain easier access to the country.

Our selectivity index based on the nationality of the migrant, $MPS_{o}^{nat}$, differs from the previous two as it is bilateral, tracking the restrictiveness for each origin-destination pair. While we will use this bilateral variable directly in our gravity estimations, we also construct an aggregated version at the destination country level. This resulting index, MPS ^nat, is compatible with the skill and resource selectivity indexes, allowing for a straightforward characterization of migration policy selectivity. To that end, we compute the population-weighted Gini index of the cumulative nationality scores for each destination country and year. If a country treats all migrants equally, it will have a Gini score of zero, regardless of whether the country grants access to everyone or no one. As the Gini index rises, the inequality of the policy increases.Footnote ¹⁸ Unlike the skills and resources indexes, the nationality index cannot take negative values. However, it can otherwise be interpreted in the same way.

Overall, we rely on two main assumptions to compute the selectivity indexes: (i) the list of legislative changes is complete, and (ii) the dataset does not contain any errors. This allows us to go from a dataset organized according to legislative changes to one in which we track the yearly level of selectivity of destination countries’ migration policy. While it is impossible to test the validity of these assumptions, we run various robustness checks to see how the indexes change when they are relaxed. A full description of these checks can be found in Appendix A, but the general conclusion is that the indexes remain robust.

Finally, we compare the newly constructed indexes with existing migration policy indicators. Unfortunately, a direct comparison with the source material, DEMIG, is impossible as they have a different unit of analysis. This leaves the indicators of skill selectivity constructed by Parsons et al. (Reference Parsons, Rojon, Rose and Samanani2020). There are a few notable differences. First, Parsons et al. cover supply- and demand-driven policies, while our index is restricted to the former (cf. infra). Second, while Parsons et al. (Reference Parsons, Rojon, Rose and Samanani2020) cover fewer destination countries (19 vs. 42), they cover a longer period (1970 to 2012). Third, Parsons et al. (Reference Parsons, Rojon, Rose and Samanani2020) do not compute a composite index. Instead, for each type of policy (e.g., the presence of quota, labor market tests, or a points-based system of entry and residence permits), they provide information on the presence (extensive margin) and the impact of the provision (intensive margin). To compare the Parsons et al. (Reference Parsons, Rojon, Rose and Samanani2020) indicators to our index of skill selectivity, we used the average of the 20 dummy variables (as described in their Section 4.1 Policy Systems).Footnote ¹⁹ Because of the differences in coverage, we could only match a third of our dataset: 6,391 out of the total 18,972 observations. Nevertheless, the correlation between our skill selectivity index and Parsons et al. (Reference Parsons, Rojon, Rose and Samanani2020) average is 0.471, which is quite high given the differences between both datasets.

3.3 The characteristics of migration policy in terms of selectivity

Figures 2, 3 and 4 plot the value of the three indexes of migration policy selectivity by skills, resources and nationality, respectively for the first and last year of our dataset (1990 and 2014) on a world map. For comparisons over time, the scale is fixed for each index, meaning that changes in the colors indicate a change in the selectivity scores. For each dimension, we notice an overall increase in the index values. The index also displays considerable variation between countries, but certain regional patterns emerge, particularly among European countries. Finally, despite noticeable similarities between the three indexes, their geographical distribution still differs considerably, confirming that selectivity cannot be reduced to a single dimension. This is also supported by the fairly weak cross-country correlation between MPS ^skill, MPS ^res, and MPS ^nat (see Table 1).Footnote ²⁰

Figure 2. Migration policy selectivity scores in terms of skills by destination country 1990 and 2014.

Notes: Plot of the destination country-specific migration selectivity scores with respect to skills. (a) MPS^skill values in 1990, (b) MPS^skill values in 2014. Red (blue) values indicate a migration policy that is more open to people with higher (lower) skills and more (fewer) resources. The intensity of the color correlates with the magnitude of the selectivity in policy.

Figure 3. Migration policy selectivity scores in terms of resources by destination country 1990 and 2014.

Notes: Plot of the destination country-specific migration selectivity scores with respect to economic resources. (a) MPS^res values in 1990, (b) MPS^res values in 2014. Red (blue) values indicate a migration policy that is more open to people with higher (lower) skills and more (fewer) resources. The intensity of the color correlates with the magnitude of the selectivity in policy.

Figure 4. Migration policy selectivity scores in terms of nationality by destination country 1990 and 2014.

Notes: Plot of the destination country-specific migration selectivity scores with respect to economic resources. (a) MPS^nat values in 1990, (b) MPS^nat values in 2014. Red (blue) values indicate a migration policy that is more open to people with higher (lower) skills and more (fewer) resources. The intensity of the color correlates with the magnitude of the selectivity in policy.

Table 1. Correlation between the indexes of migration policy selectivity and restrictiveness

Notes: The Table shows cross-country correlations between the different indexes of migration policy selectivity MPS ^skill, MPS ^res, and MPS ^nat constructed in this paper, and the migration policy restrictiveness index MPR taken from Rayp et al. (Reference Rayp, Ruyssen and Standaert2017). *,** and *** indicate significance at the 10%, 5% and 1% respectively.

Focussing on the change in selectivity over time, Figure 5 maps the average selectivity score for all 42 countries in the database. It also shows the average scores of four sub-groups: OECD and non-OECD countries, with the former subdivided into EU and non-EU members. This split-up separates countries according to economic and institutional characteristics and filters out the popular and traditional migrant destinations. The composition of each group is listed in Appendix B. Overall, policy selectivity in the three dimensions increases continuously throughout our sample. Migration policy moves from moderately negatively skill-selective (i.e., favoring low-skilled workers) to outspokenly positively skill-selective. Similarly, in terms of economic resources, migration policy steadily changes from mildly to strongly selective. In contrast, nationality selectivity is initially limited, but access suddenly becomes much more unequal from the 2000s onwards.

Figure 5. Evolution in migration policy selectivity, (a) MPS^skill, (b) MPS^res, (c) MPS^nat. Notes: Plot of the yearly average values of the migration policy selectivity indexes with respect to skills (a), economic resources (b) and nationality (c) for all countries and subgroups.

Despite institutional, geographic and economic differences, the increase in policy selectivity is reasonably homogeneous across country groups. The ranking between the four groups remains stable for all but the nationality indexes. The non-EU OECD countries, like Australia, are consistently the most selective and the EU countries the least selective. The patterns are much less stable for selectivity based on nationality. The average non-OECD country remains close to its initial, low level. The OECD member countries, in contrast, witness a sudden spike in nationality-based selectivity from the 2000s onwards. That increase stops for the EU members after the 2004 expansion of the EU toward Central and Eastern European countries. Simultaneously, the non-EU OECD countries see another peak in their levels of selectivity by nationality, rapidly surpassing the levels of all other groups.

Summarizing the overall pattern, we note that the non-EU OECD countries are the most selective in their migration policies. The primary basis for selectivity in the migration policy of EU countries is nationality, but this is not to say that EU countries do not select on resources or skills. Non-OECD countries primarily select migrants based on skills and resources, but this group also shows more heterogeneity. Only the selectivity in terms of economic resources displays a similar pattern for all groups in our dataset.

To assess the significance of the differences in average migration policy selectivity along the different dimensions between the country groups, we perform t-tests on the group mean differences for all indexes. Table 2 shows the results for four reference years (the first, final and two intermediate years). It shows that EU countries are consistently less selective on skills than non-EU OECD countries. However, the initial significant difference between the EU and the non-OECD countries disappears after the 2000s, as the EU countries increase their level of skill selectivity. In terms of economic resources, the t-tests confirm the pattern of convergence shown in Figure 5 as the differences are insignificant by the end of the period. Regarding nationality-based selectivity, OECD countries are significantly more selective than non-OECD countries for the whole period. The differences in nationality-based selectivity within OECD countries do not appear statistically significant.

Table 2. Differences in average selectivity along the different dimensions between country groups

Notes: The Table displays the results of t-tests on the country group mean differences in migration policy selectivity for all indexes of selectivity MPS ^skill, MPS ^res, and MPS ^nat for four different reference years (the first and final year in our sample and two intermediate years). *,** and *** indicate significance at the 10%, 5% and 1% respectively.

Finally, we may wonder how selectivity is related to and distinct from restrictiveness. We address this question by looking at the correlation between the different migration policy selectivity indexes and an index of migration policy restrictiveness (MPR). Specifically, we use the index provided by Rayp et al. (Reference Rayp, Ruyssen and Standaert2017), which covers a comparable period and country sample to ours but is limited to OECD countries. The correlations (for all years and countries) reported in the last row of Table 1 are either insignificant or weakly negative. This points to a trade-off in migration policy between selectivity and restrictiveness: i.e., more liberal countries to migration tend to be more open toward some migrants than toward others. This is in line with the findings of Ruhs (Reference Ruhs2013), who found a trade-off between the openness of (labor) migration policy and the level of (skill) selectivity. Moreover, the weakness of this correlation implies that the characterization of migration policy cannot be reduced to its degree of restrictiveness alone. Restrictiveness and selectivity should be considered as separate dimensions of migration policy.

4.1 Model specification and estimation method

The three indexes of selectivity constructed in the previous Section allow us to expand the scope and depth of the analysis of migration policy. The model we use to analyze the effectiveness of migration policies is derived from the standard random utility maximization (RUM) framework, which has become the consensus model used to understand the location decision of migrants.Footnote ²¹ As argued by Grogger and Hanson (Reference Grogger and Hanson2011), the effectiveness of policy selectivity refers to its impact on the scale or the structure of the targeted migration flows.Footnote ²²

The general specification of the scale equation is as follows:

(1)$$M^{k}_{odt} = \alpha^{k}_{1} MP_{odt-i} + \alpha^{k}_{2} Z_{odt-1} + \delta^{k}_{od} + \delta^{k}_{ont} + \varepsilon^{k}_{odt},\; \qquad {k = skill,\; res,\; nat}$$

where $M^{k}_{odt}$ denotes the flow of migrants from country o to country d at time t, and n groups together different sets of destination countries. The superscript k indicates the inflow of skilled (skill), economically well-endowed (res), or all migrants (nat). MP _odt−i and Z _odt−1 are vectors containing lagged migration policy variables and control variables, respectively.

For the migration of the high-skilled and economically well-endowed, we also estimate the structure equation, which takes the following general form:

(2)$${M^{k}_{odt}\over M_{odt}} = \beta^{k}_{1} MP_{odt-5} + \beta^{k}_{2} Z_{odt-1} + \mu^{k}_{od} + \mu^{k}_{ont} + \eta^{k}_{odt},\; \qquad {k = skill,\; res}$$

where the dependent variable reflects the share of migrants from a specific category, i.e., either the high-skilled or the economically well-endowed. While not identical, equation (2) is equivalent to the structure equation strictu sensu of Grogger and Hanson (Reference Grogger and Hanson2011). In case of positive selection, e.g., due to migration policy, the share of the targeted group in the total bilateral flow should be higher.

Both Eqn (1) and (2) are estimated using the Poisson pseudo-maximum likelihood (PPML) estimator, as this allows to include zero migration flows and controls for heteroskedasticity (Santos Silva and Tenreyro, Reference Santos Silva and Tenreyro2006). For the scale equation (1), we specify a model that applies to all groups of migrants that we consider.Footnote ²³ We use the same specification for the structure equation (2) given that it is essentially the ratio of two scale equations. The policy component of bilateral costs (MP _odt−1) contains the three indexes of policy selectivity we constructed (MPS ^skill, MPS ^res and MPS ^nat) as well as an index of policy restrictiveness (MPR). The migration policy variables are lagged to control for potential contemporaneous reverse causality and allow for the delay with which migration policy rules usually come into effect. In the skill and resources regressions, this necessitates 5-year lags (i = 5) as the dependent variable captures the net five year migration flow. As the nationality regressions have yearly migration flow data, we only require a one-year lag (i = 1).

As control variables, we include the common explanatory variables in the literature on the determinants of international migration. Z _odt−1 contains the difference in earnings between origin and destination as proxied by their relative GDP per capita;Footnote ²⁴ the origin-specific stock of migrants in each destination country as an indicator of the network component of migration costs; and the unemployment rate and income inequality in the destination country as proxies for economic opportunity, all lagged by one year and expressed in logs.Footnote ²⁵ Other usual proxies for migration costs like bilateral distance, common colonial history, former colony and common language are captured by the origin-destination fixed effects.

Table 3. Estimation results for skilled migration (scale and structure)

Notes: Standard errors are clustered at the destination-time level. ***, **, and * indicates significance at the 1%, 5%, and 10% level.

Both the scale and structure equations include origin-nest-time ($\delta ^k_{ont}$ and $\mu ^k_{ont}$) and origin-destination fixed effects ($\delta ^k_{od}$ and $\mu ^k_{od}$). The first control for international correlation in migration policy across destinations and time. For example, the European Union often implements European-wide migration policy measures and ignoring this would bias the results downward.Footnote ²⁶ To control for this, we group the destinations into different nests and use those to construct origin-nest-time fixed effects (cf. Bertoli and Fernández-Huertas Moraga, Reference Bertoli and Fernández-Huertas Moraga2013, Reference Bertoli and Fernández-Huertas Moraga2015). We identify destination-nests using two criteria: (i) the likelihood of correlation between migration policies, i.e., the likelihood that destinations are substitutes for potential migrants; and (ii) keeping the number of nests small to reduce the risk of an incidental parameter problem.Footnote ²⁷ This results in the following nest definition: (1) Europe (including the UK), (2) the New World (US, Canada, Australia and New Zealand), and (3) the rest of the world.Footnote ²⁸ The origin-destination fixed effects control for the unknown initial levels of the migration policy selectivity variables,Footnote ²⁹ as well as any residual, time-invariant multilateral resistance to migration that varies between the destination countries within a nest.

Finally, the scale and structure equations are estimated from origin-destination-time specific observations, but include destination-time determinants common to all origins (such as MPS ^skill, MPS ^res and MPR). In addition, as the number of origins is destination-specific, the residual errors of the estimated models are likely to be correlated by destination. To control for this, we cluster the standard errors by destination-time (see e.g. Angrist and Pischke, Reference Angrist and Pischke2009, pp. 308–312).

4.2 Data

Except for the policy variables, all explanatory variables used to estimate equations (1) and (2) come from standard sources provided by the OECD, the World Bank and CEPII. In addition to the indexes of migration policy selectivity, we also use an indicator of overall restrictiveness from Rayp et al. (Reference Rayp, Ruyssen and Standaert2017). Higher values of this index correspond to lower levels of restrictiveness. The complete list of sources can be found in Appendix C.

Data on migration flows, disaggregated by the migrant characteristics (e.g., skills and resources), is harder to come by. In particular, Czaika and Parsons (Reference Czaika and Parsons2017) expound on the difficulties in comparable cross-country statistics. They use different detailed national data sources to construct a harmonized dataset that, unfortunately, is not publicly available. Alternatively, Bélot and Hatton (Reference Bélot and Hatton2012) use the information on migrant stocks broken down by educational level for the year 2000 or 2001 taken from the DLM database of Docquier et al. (Reference Docquier, Lowell and Marfouk2009).

In this study, we use migration data from two sources. First, to capture the bilateral flows by skill level and economic resources, we rely on the OECD's Database on Immigrants in OECD and non-OECD Countries (DIOC).Footnote ³⁰ Based on population censuses and registers, DIOC provides information on demographic and labor market characteristics of the foreign population by country of birth for 34 OECD destination countries and 235 countries of origin. This data is collected at four different points: 2000/2001, 2005/2006, 2010/2011 and 2015/2016.Footnote ³¹ This dataset includes a variable listing the migrants’ highest level of education, distinguishing between four broad aggregates based on the ISCED classification. The “tertiary education” category (ISCED levels 5A, 5B and 6) is used as a proxy for the stock of skilled migrants. The bilateral inflow of skilled migrants is proxied by the change in the stock of high-skilled migrants. Negative values were dropped from the sample.

DIOC does not provide direct information on migration by economic resources connected to policy selectivity along this dimension – nor are we aware of any other dataset that does. However, DEMIG defines selectivity in terms of economic wealth as those policy changes that target “investors, businesspeople and entrepreneurs” (see footnote 10). Therefore, to proxy the number of economically well-endowed migrants, we use the breakdown of immigrants by ISCO-88 occupation category provided in DIOC.Footnote ³² The closest match that can be found in DIOC for the DEMIG category of economically well-endowed migrants are the migrants classified in the ISCO-88 category 1 (“Legislators, senior officials, corporate managers and general managers”).Footnote ³³

While the DIOC database is one of the most detailed and accurate sources of migration data broken down by education level or occupation category for the destination countries under consideration, it has several drawbacks. First, it only provides information on the stock of migrants. As such, any flow data derived from it will measure net rather than gross migration flows. Second and more importantly, the DIOC database only provides information every five years, and a significant fraction of country-pairs are missing in the 2005/2006 sample. Taking the difference between two consecutive stock measurements results in a considerable reduction in sample size, and in the number of destination countries.Footnote ³⁴ This limited sample size may compromise the representativeness and reliability of the analysis. To address this, we used the Bayesian state-space model of Standaert and Rayp (Reference Standaert and Rayp2022) to fill in the gaps in the DIOC database and obtain a more representative sample. The state-space model combines data on migration stocks and flows from different sources together with a model of demographic evolution to fill in missing observations with the most likely value. A full description of the imputation algorithm can be found in Appendix D. The bilateral migrant stock series we obtain in this way extends the range of destination countries to 30 for skilled migration and to 27 for the economically well-endowed.

For the nationality-based selectivity, we can rely on the International Migration Database (IMD) of the OECD (see OECD, 2021). In contrast to the DIOC data, the IMD provides annual data on the bilateral gross flow of migrants and bilateral migrant stocks (used in the analysis as a proxy for network effects) since 2000. The choice of yearly data for these regressions allows us to make maximum use of the available information and variation in our data so as to capture any short-term impact of changes in migration policies.