3.2.1. Asset value functions

Let $\mathcal{J}_{os}^{F}$ and $\mathcal{J}_s^V$ denote the value associated with a filled and unfilled vacancy, respectively.Footnote ¹⁰ Then, their flow value in steady state is given by:

(6) \begin{align} r \mathcal{J}_{os}^{F} &= p_{os} - w_{os} - \left(\delta _{os}+g_o \right) \left [ \mathcal{J}_{os}^{F}-\mathcal{J}_s^V \right ] \end{align}

(7) \begin{align} r \mathcal{J}_s^V &= -c_s+q(\theta _s) \left [ \left(1-\phi _s \right) \mathcal{J}_{ns}^{F} +\phi _s \mathcal{J}_{ms}^{F}-\mathcal{J}_s^V \right ], \end{align}

where $c_s$ is the fixed cost of an open vacancy for a worker of skill level $s$ , $\phi _s \equiv U_{ms}/U_s$ is the share of unemployed immigrants among all searching individuals of skill type $s$ , $g_o$ is the retirement rate for individuals of origin $o$ , and $\delta _{os}$ is the exogenous separation rate, which is allowed to differ for workers’ skills and country origin. Equation (6) states that the asset value of a filled vacancy is given by the price at which the intermediate input is sold, minus the wage rate paid to employed workers, and the expected value of breaking up with an employed worker, multiplied by the probability that such an event occurs, $\delta _{os}+g_o$ .Footnote ¹¹ Equation (7) has a similar interpretation, as it states that the asset value of having an unfilled vacancy is given by the vacancy cost, $-c_s$ , plus the expected value of filling a vacancy, which occurs at a probability $q(\theta _s)$ .

For working-age individuals who supply labor, the steady-state discounted present value of employment, $\mathcal{J}_{os}^{E}$ , and unemployment, $\mathcal{J}_{os}^{U}$ , are given by:

(8) \begin{align} r\mathcal{J}_{os}^{E}&= (1-\tau )w_{os}+\delta _{os}\!\left [ \mathcal{J}_{os}^{U}-\mathcal{J}_{os}^{E}\right ]+g_o \!\left [ \mathcal{J}_{os}^R-\mathcal{J}_{os}^E \right ] +T^y_{os}+r k^y_{os} \end{align}

(9) \begin{align} r\mathcal{J}_{os}^{U}&= b_{os}+m\!\left( \theta _{s}\right) \left [ \mathcal{J}_{os}^{E}-\mathcal{J}_{os}^{U}\right ]+g_o \!\left [ \mathcal{J}_{os}^R-\mathcal{J}_{os}^U \right ]+T^y_{os}+r k^y_{os}, \end{align}

where $\tau$ is the labor income tax rate, $T^y_{os}$ and $r k^y_{os}$ are, respectively, redistributive transfers and capital income of young workers of origin $o$ and skill $s$ ,Footnote ¹² and $\mathcal{J}_{os}^R$ is the steady-state value of retirement which is defined later on in the paper. According to equation (8), the flow value of being employed equals the difference between the after-tax wage income and the expected loss from breaking up from the firm, plus transfers, $T^y_{os}$ , capital income, $r k^y_{os}$ , and the expected gain from becoming a retiree, $g_o [ \mathcal{J}_{os}^R-\mathcal{J}_{os}^E ]$ . Likewise, equation (9) states that the flow value of unemployment equals its return, that is, the unemployment benefit $b_{os}$ , plus the probability of finding a job, multiplied by the expected gain from such event, transfers, capital income, and the expected gain from retirement.

Finally, denoting with $R_{os}$ the number of retired workers and $Q_{os}$ the total amount of active workers of type $(o,s)$ , the flow value of being a retired worker in steady state, $\mathcal{J}_{os}^R$ , can be written as:

(10) \begin{equation} r\mathcal{J}_{os}^R= T^R_{os}+r k^R_{os}-\nu \mathcal{J}_{os}^R, \end{equation}

where $T^R_{os}$ are redistributive transfers paid to retired workers and $k^R_{os}$ is the share of capital held by retired workers.

3.2.2. Job creation condition

As intermediate firms are in perfect competition and bare no costs of entry, they will find it profitable to enter the market as long as the value of posting a new vacancy is greater than zero. In steady state, the free entry condition is thus given by:

(11) \begin{equation} \mathcal{J}_{s}^{V}=0. \end{equation}

Combining equations (6), (7), and (11), in steady state, the job creation condition reads:

(12) \begin{equation} \frac{c _{s}}{q\!\left( \theta _{s}\right) }=\left( 1-\phi _{s}\right) \left [ \frac{p_{ns}-w_{ns}}{r+g_n+\delta _{ns}}\right ] +\phi _{s}\!\left [ \frac{p_{ms}-w_{ms}}{r+g_m+\delta _{ms}}\right ]. \end{equation}

Equation (12) states that the expected cost of creating a vacancy, $c_{s}/q ( \theta _{s} )$ , is equal to the expected benefit of filling a vacancy with either a native or immigrant worker, $p_{os}-w_{os}$ , adjusted by the worker-type specific discount rate, $r+g_o+\delta _{os}$ . Note that a higher market tightness $\theta _s$ translates to higher vacancy opening costs, since the waiting time for filling a vacancy is increasing in $\theta _s$ .

3.2.3. Wage determination

Following mainstream search and matching literature, wages are determined through a Nash-bargaining process. The surplus created when a job seeker $U_{os}$ and a vacancy $V_s$ meet leads to a negotiation over the wage rate $w_{os}$ . For the worker accepting a job offer would generate a surplus of $\mathcal{J}_{os}^F - \mathcal{J}_s^V$ , whereas for the firm hiring an additional worker would generate a gain of $\mathcal{J}_{os}^E-\mathcal{J}_{os}^U$ . The outcome of the bargaining process is the wage rate $w_{os}$ that solves the following maximization problem:

\begin{equation*} w_{os}= \mathrm{argmax} \!\left(\mathcal {J}_{os}^E-\mathcal {J}_{os}^U\right)^{\beta }\left( \mathcal {J}_{os}^F - \mathcal {J}_s^V \right)^{1-\beta }, \end{equation*}

where $\beta \in (0,1)$ denotes the worker bargaining power. The first-order maximization condition derived from the above equation satisfies:

(13) \begin{equation} \left( 1-\beta \right) \left( \mathcal{J}_{os}^{E}-\mathcal{J}_{os}^{U}\right) =\beta \!\left( \mathcal{J}_{os}^{F}-\mathcal{J}_{s}^{V}\right). \end{equation}

Combining equation (13) with the asset value equations (6)–(9) and considering the free entry condition (11), the bargained wage rate paid to workers of type $(o,s)$ is given by:

(14) \begin{equation} w_{os}=\frac{\beta \!\left [ r+g_o+\delta _{os}+m\!\left( \theta _{s}\right) \right ] p_{os}}{\left( r+g_o+\delta _{os}\right) \left [ 1-\left( 1-\beta \right) \left( \tau +\mu \right) \right ] +\beta m\!\left( \theta _{s}\right) }, \end{equation}

where the unemployment benefit $b_{os}$ has been endogenized and proportionally set to the wage rate, that is, $b_{os} \equiv \mu w_{os}$ , with $\mu \in (0,1)$ denoting the replacement rate. According to equation (14), higher worker bargaining power $\beta$ translates to higher wage rates. It is also easy to check that the bargained wage rate $w_{os}$ is increasing in the replacement rate $\mu$ . This is coherent with the intuition that higher values of replacement rate would increase the worker’s outside option and, thus, the worker’s surplus from hiring.

3.2.4. Employment and retirement

The dynamic law of employed workers of skill $s$ and origin $o$ is given by the difference between the amount of matches formed and the breakups that take place in a given instant of time $t$ , that is:

(15) \begin{equation} \dot{E}_{os}=m\!\left( \theta _s \right) U_{os}-\left(\delta _{os}+g_o\right) E_{os}. \end{equation}

Similarly, the dynamic law of retired workers of skill $s$ and origin $o$ is given by the difference between the workers who retire and the retirees that die in a given instant of time $t$ , that is:

(16) \begin{equation} \dot{R}_{os}=g_o Q_{os}-\nu R_{os}. \end{equation}

Recalling that $Q_{os} \equiv E_{os}+U_{os}$ is the total amount of active individuals of type $(o,s)$ , the number of employed, unemployed, and retired people in steady state can be written as:

(17) \begin{align} E_{os}& =\frac{m\!\left( \theta _{s}\right) Q_{os}}{\delta _{os}+g_o+m\!\left(\theta _{s}\right) } \end{align}

(18) \begin{align} U_{os}& =\frac{\left(\delta _{os}+g_o\right)Q_{os}}{\delta _{os}+g_o+m\!\left( \theta _{s}\right) } \end{align}

(19) \begin{align} R_{os}& =\frac{g_o}{\nu }Q_{os}. \end{align}

Based on equations (17) and (18), for any given size of the active population $Q_{os}$ , employment is increasing in the job-finding probability, $m(\theta _s)$ , and decreasing in the separation rate, $\delta _{os}$ . Also note that, according to equation (19), an in increase in active population translates to more retirees in the steady state. It is worth pointing out that, because immigrants and natives have different retirement rates, a variation in the quantity of active workers type $o$ is able to affect the host country dependency ratio $\sum \limits _{o} \sum \limits _{s} (R_{os}/Q_{os})$ .

4.1.1. Calibration of common parameters

Table 1 reports exogenous parameters without country variation. We set the capital share parameter $\alpha =0.33$ to match the empirical evidence of Gollin (Reference Gollin2002). Following Ottaviano and Peri (Reference Ottaviano and Peri2012), we choose the elasticity of substitution between skill groups and origin groups of, respectively, $\sigma _1 =2$ and $\sigma _2 =20$ . In line with Chassamboulli and Palivos (Reference Chassamboulli and Palivos2014) and Battisti et al. (Reference Battisti, Felbermayr, Peri and Poutvaara2018), the monthly interest rate $r$ is set to $0.4\%$ . Further, we choose the matching elasticity parameter $\epsilon =0.5$ , which is within the range of estimates reported in Petrongolo and Pissarides (Reference Petrongolo and Pissarides2001) and Mortensen and Nagypal (Reference Mortensen and Nagypal2007), and the bargaining power $\beta =0.5$ , so that the Hosios condition is met [see Hosios (Reference Hosios1990)]. Finally, we normalize the low-skilled vacancy cost $c_l$ to the same value adopted in Battisti et al. (Reference Battisti, Felbermayr, Peri and Poutvaara2018).Footnote ¹⁷

Table 1. Parameters without country variation

4.1.2. Calibration of country-specific parameters

Exogenous parameters varying across countries are listed in Table 2. The TFP parameter $A$ is set to match the TFP levels at current PPPs from the Penn World Table 10 database for each of the considred OECD countries. The matching efficiency parameter $\xi$ is instead set to match the monthly job-finding rates reported by Hobijn and Şahin (Reference Hobijn and Şahin2009) for each country.Footnote ¹⁸ Further, the parameter $x$ is calibrated to match the average return to skill $w_h/w_l$ according to the Education at Glance 2012 report of the OECD (2012), whereas $\lambda$ is calibrated to match the average native wage premium $w_n/w_m$ obtained from Docquier et al. (Reference Docquier, Ozden and Peri2014). The separation rates $\delta _{os}$ are set to match the unemployment rates observed in the DIOC data. Specifically, separation rates are calibrated to be, on average, larger for migrants than for natives, since migrant workers are generally characterized by a higher unemployment rate. The vacancy costs ratio $c_h/ c_l$ is set equal to the wage ratio $w_h/w_l$ , implying that it is more costly to have a high-skilled unfilled vacancy, rather than a low-skilled one, proportionately to the education wage premium.Footnote ¹⁹ The upper bound parameter related to the cost of acquiring education, $\bar{z}$ , is set in order to match the share of high-skilled natives provided by DIOC data.

Table 2. Parameters varying across countries

As far as fiscal parameters are concerned, the replacement rate $\mu$ matches the share of unemployment benefits in GDP obtained from the Annual National Accounts harmonized by the OECD. In line with Burzynski et al. (Reference Burzynski, Docquier and Rapoport2018) and Aubry et al. (Reference Aubry, Burzynski and Docquier2016), we calibrate the level of public transfers to each cohort so to match the government expenditure to GDP, taken from the OECD Annual National Accounts, as well as the data on social protection expenditures included in the Social Expenditure Database (SOCX) of the OECD. More precisely, the SOCX database includes internationally comparable statistics on public social expenditures at the program level as well as net social spending indicators. We extract the data on expenditures linked to pension benefits, sickness and disability, family and children transfers as well as other transfers, as percentage of total social protection expenditures. Next, we disaggregate education expenditures and all social protection expenditures by education, age, and origin using the European Union Statistics on Income and Living Conditions (EU-SILC) provided by Eurostat for European countries, and the fiscal profiles used in Chojnicki et al. (Reference Chojnicki, Docquier and Ragot2011) for the USA, Canada, and Australia. We then extract personal characteristics, data on social benefits, and the sampling weight of each individual. The amount of benefits received by each individual type $({a,o,s})$ is then computed and rescaled to match the aggregate level obtained from the SOCX database.

Finally, we normalize the total young native workers population to one and parametrize the number of young immigrants by skill ( $Q_{mh}$ and $Q_{ml}$ ) according to the DIOC data on active individuals of age 25–64 years by origin. The retirement rates $g_n$ and $g_m$ are set in order to match the shares of total individuals of age 65 years and over by origin $\Big(R_n \equiv \sum \limits _s R_{ns} \text { and } R_m \equiv \sum \limits _s R_{ms}\Big)$ , while the birth rate $\nu$ is calibrated to match the monthly growth rate of the labor force during the period 2002–2010 in the analyzed OECD countries.

Using this calibration, in the following section, we simulate marginal increases in different types of migration flows taking as reference the described moments as the status quo.Footnote ²⁰

4.2.1. The welfare effects of immigration

Figure 2 describes the effects of immigration on native welfare in the selected 19 OECD countries. In particular, Figure 2(a) shows the average welfare effects of low-skilled, high-skilled, and skill-balanced immigration on the aggregate group of the selected OECD countries, weighted for their native population size (which includes retirees for the benchmark model and Model 3, but only working-age active natives for Models 2 and 4) in order to account for the differences in countries size. The welfare effect on immigration is on average quite modest under the benchmark model, as it ranges from −0.08% (low-skilled immigration scenario) to 0.18% (high-skilled immigration scenario). The model versions abstracting from the presence of retirees (i.e., Model 2 and Model 4) are the most pessimistic ones under all of the three analyzed scenarios (especially Model 2, which ranges from −0.21% in the low-skilled immigration scenario to 0.06% in the high-skilled scenario). These are also the model versions that differ the most from the benchmark model, implying that taking into account the age structure of immigrants and natives plays an important role in the evaluation of the welfare effects of immigration. As far as the introduction of endogenous skill adjustment is concerned, the model version that differs from the benchmark for the only absence of native skill adjustment (i.e., Model 3) yields slightly more pessimistic results in the low-skilled scenario (average native welfare decreases by 0.12%), but more optimistic results in the high-skilled scenario (average native welfare increases by 0.25%) when compared with the benchmark model. In the skill-balanced scenario, both the benchmark model and Model 3 yield negligible effects on the average native welfare of the aggregate group of the considered OECD countries (average native welfare increases by less than 0.01% in both model versions).

Figure 2. Effects of immigration (1% of the total labor force) on native welfare in the 19 selected OECD countries.

Note: Benchmark = Retirees & Endogenous Skill Acquisition; Model 2 = No Retirees; Model 3 = Exogenous Skill Acquisition; and Model 4 = No retirees & Exogenous Skill Acquisition. Countries are ranked in descending order according to the native welfare effect in the benchmark model. Variations are expressed in percentage points.

Figure 2(b)–(d) show the effects of the three immigration shocks—low-skilled, high-skilled, and skill-balanced immigration—by country. According to our benchmark model, the countries that benefit the most from migration in all of the three scenarios are those characterized by a share of elderly immigrants that is much lower than the share of elderly natives (cfr. Figure 1(a) in Section 2). Unsurprisingly, the high-skilled immigration scenario is the more optimistic one for most countries (under the benchmark model, native welfare increases in all countries but Sweden, Denmark, and France). The skill-balanced immigration scenario also improves native welfare on most countries (14 out of 19 under the benchmark model). On the contrary, the low-skilled immigration scenario is the most pessimistic one for most countries (natives benefit from low-skilled immigration only in 7 out of 19 countries under the benchmark model).

4.2.2. Welfare effect decomposition

To shed light on the mechanisms at work behind the simulations results we presented, we decompose the average welfare effect into different transmission channels: employment, gross wage, fiscal, capital, education cost, and residual effect channels. Indeed, using equation (25), variations in native welfare can be decomposed as:

\begin{equation*} \Delta \mathcal {W}_n= \sum \limits _s \left. \Delta \mathcal {W}_n\right |_{\text{empl}_s}+\sum \limits _s \left. \Delta \mathcal {W}_n\right |_{\text{wage}_s}+\left. \Delta \mathcal {W}_n\right |_{\text{fiscal}}+\left. \Delta \mathcal {W}_n\right |_{\text{capital}}+\left. \Delta \mathcal {W}_n\right |_{\text{educ}}+\left. \Delta \mathcal {W}_n\right |_{\text{resid}}, \end{equation*}

where

\begin{align*} &\left. \Delta \mathcal{W}_n\right |_{\text{empl}_s} \equiv \frac{\left( 1-\tau \right) \left(\Delta E_{ns} \right) w_{ns}+\mu \!\left(\Delta U_{ns} \right) w_{ns}}{\sum \limits _s \!\left(Q_{ns}+R_{ns}\right)}\\ &\left. \Delta \mathcal{W}_n\right |_{\text{wage}_s} \equiv \frac{ \left( 1-\tau \right) \left( \Delta w_{ns} \right) E_{ns} +\mu \!\left( \Delta w_{ns} \right) U_{ns}}{\sum \limits _s \!\left(Q_{ns}+R_{ns}\right)}\\ &\left. \Delta \mathcal{W}_n\right |_{\text{fiscal}} \equiv -\frac{\Delta \tau \sum \limits _s E_{ns} w_{ns}}{\sum \limits _s \!\left(Q_{ns}+R_{ns}\right)}\\ &\left. \Delta \mathcal{W}_n\right |_{\text{capital}} \equiv \frac{r \sum \limits _s \sum \limits _a \Delta k^a_{ns}}{\sum \limits _s \!\left(Q_{ns}+R_{ns}\right)}\\ &\left. \Delta \mathcal{W}_n\right |_{\text{educ}} \equiv -\frac{\left( r+g_n\right) \left [ \left( \Delta z^* \right) Q_{nh} + \left( \Delta Q_{nh} \right) z^* \right ] }{2 \sum \limits _s \!\left(Q_{ns}+R_{ns}\right)} \\ &\left. \Delta \mathcal{W}_n\right |_{\text{resid}} \equiv \frac{ \sum \limits _s \!\left( \Delta Q_{ns} \right) T^y_{ns} + \sum \limits _s \!\left( \Delta R_{ns} \right) T^R_{ns} }{\sum \limits _s \!\left(Q_{ns}+R_{ns}\right)}. \end{align*}

Figure 3 gives the weighted mean averages of the labor market-related welfare components (employment and wage transmission channels by skill), whereas Figure 4 gives the weighted mean averages of the other transmission channels (fiscal, capital, education, and residual).Footnote ²² For the sake of comparability, in all of these figures, we use the same vertical scale.

Figure 3. Decomposition of the average welfare effect of immigration (1% of the total labor force) — employment and wage channels.

Note: Benchmark = Retirees & Endogenous Skill Acquisition; Model 2 = No Retirees; Model 3 = Exogenous Skill Acquisition; and Model 4 = No retirees & Exogenous Skill Acquisition.

Figure 4. Decomposition of the average welfare effect of immigration (1% of the total labor force) — fiscal, capital, education, and residual channels.

Note: Benchmark = Retirees & Endogenous Skill Acquisition; Model 2 = No Retirees; Model 3 = Exogenous Skill Acquisition; and Model 4 = No retirees & Exogenous Skill Acquisition.

Figure 3(a) and (b) show that when natives endogenously decide whether to invest in education (i.e., in Benchmark and Model 2), the employment transmission channel contributes to welfare variations in a meaningful way only in case of skill-biased immigration. In particular, endogenous skill adjustment asymmetrically amplify the job creation effects for low- and high-skilled jobs so that there is a positive job creation effect for natives employed in the skill sector that is not directly affected by the immigration shock, but a negative job creation effect for those natives working in the same skill sector of the new immigrants. This is because, in case of low-skilled (high-skilled) immigration, more natives will find it profitable to (to not) invest in education and apply for high-skilled (low-skilled) positions, so to avoid a fiercer competition from the new immigrants in the low-skilled (high-skilled) sector. As a result, the welfare effect contribution due to the presence of high-skilled (low-skilled) workers increases, whereas that of low-skilled (high-skilled) workers decreases. This same mechanism does not operate in those model versions where natives are not allowed to upgrade their skill in face of migration. Indeed, in Models 3 and 4, the employment effect only depends on the market tightness, which results to not be particularly sensible to immigration shocks. As a consequence, the employment transmission channel does not significantly contribute to variations in native welfare under Models 3 and 4.

Figure 3(c) and (d) illustrate the contribution of the wage transmission channel on the obtained welfare results. Interestingly, this channel is not particularly sensitive to differences in the model versions. Indeed, wage variations are mainly driven by complementarity effects in production between low- and high-skilled workers: an increase of low-skilled (high-skilled) migrant employment makes marginal productivity of high-skilled (low-skilled) workers increase, leading to a higher high-skilled (low-skilled) labor income. This holds true regardless of the considered model version, as they all share the same production function structure.

As far as the direct fiscal contribution of the immigration shocks is concerned, Figure 4(a) gives noticeably less pessimistic results when retired workers are included in the model (i.e., in Benchmark and Model 3). In particular, the fiscal contribution in the high-skilled immigration scenario turns positive, while the negative fiscal effect of low-skilled and skill-balanced immigration shrinks with the introduction of retirees in the model. This is because retirees tend to be a weighty fiscal burden (retired workers have access to pension benefits and stop contributing to the fiscal revenues as they leave the labor market) and, at the same time, immigrants in the host countries are, on average, characterized by a lower share of retirees. Furthermore, the result that high-skilled and low-skilled immigration have different fiscal impacts is given by the differences in their unemployment rates (high-skilled workers are characterized by a lower unemployment rate, which translates to a lower government expenditure on unemployment benefits) and welfare usage.

Figure 4(b) displays the welfare effect of immigration that takes place through the capital accumulation channel. High-skilled immigration stimulates native capital accumulation, whereas low-skilled immigration hampers native capital accumulation in per capita terms (i.e., the capital dilution effect takes place) across all model variants. Indeed, recalling that the capital accumulation transmission channel takes into account native capital in per capita terms, $\sum \limits _s \sum \limits _a k_{ns}^a \equiv \left(\sum \limits _s Q_{ns} + \sum \limits _s R_{ns}\right)K/\left(\sum \limits _o \sum \limits _s Q_{os} + \sum \limits _o \sum \limits _s R_{os}\right)$ , the resulting effect depends on whether the increase in aggregate capital $K$ is able to offset the increase in the total population $\left(\sum \limits _o \sum \limits _s Q_{os} + \sum \limits _o \sum \limits _s R_{os}\right)$ due to the inflow of new immigrants. As in almost all of the considered countries, the share of low-skilled workers is much higher than that of high-skilled workers, increasing the number of the scarcer and more productive input, that is, the high-skilled workers, leads to a positive complementary effect that is stronger than any capital dilution effect that may take place in the host economy. On the contrary, the complementary effect taking place in response to low-skilled immigration turns out to be unable to counteract the capital dilution effect.

Finally, Figure 4(c) and (d) show the education cost and residual transmission channels, respectively. Both channels are necessarily equal to 0 in the models where natives skill distribution cannot change in response to immigration shocks (Models 3 and 4), as education cost is exogenous and the residual channel depends on the changes on natives skill distribution. Focusing our attention on the benchmark model and Model 2, the results on the education cost channel are quite intuitive: when new low-skilled immigrants enter the labor market, more natives find it profitable to invest in education, making both total and average cost in education increase. In the case of high-skilled immigration, a specularly symmetric scenario takes place, that is, a lower number of natives invest in education, making the education cost decrease. The residual effect is still negligible under both the benchmark model and Model 2, as natives skill adjustment does not noticeably affect the weight of the redistributive transfers on the average native welfare.