2. An NDC framework

A generic NDC scheme, in principle, is a combination of a financial traditional defined contribution (DC) pension scheme and a PAYG financing (i.e., contributions from current workers are used to pay for pension benefits of current pensioners). As in the common DC plan, participants contribute a fixed fraction of earnings throughout their working life; however, the account balances under the NDC system are fictitious (or notional) since no actual money is accumulated, and so the individual effectively acquires a series of individual claims on the public pension budget. The return on these contributions, in contrast to a financial defined contribution scheme, is a notional interest rate created by the government, generally linked to wage growth or GDP growth rather than a return on financial assets.

The amount of pension benefits under an NDC pension scheme is based on the concept of an individual lifetime account. At retirement, the amount of the account balance is converted into a lifetime pension according to standard actuarial practice. The initial pension at retirement is expressed in the general form as:

(1)$$\hbox{Initial pension at retirement} = \displaystyle{{\hbox{Accumulated notional capital}} \over {\hbox{Annuity divisor}}}.$$

• • Notional capital

Under an NDC scheme, the individual notional account grows with new contributions plus (notional) returns on the account. Additionally, among countries implementing this system, only Sweden distributes the notional capital of persons who die during the accumulation phase to the account values of survivors belonging to the same birth cohort. This capital, known as ‘inheritance gains’ or the ‘survivor dividend’, constitutes a part of the notional capital used to calculate the initial pension when people retire.Footnote ⁶ Following Boado-Penas and Vidal-Meliá (Reference Boado-Penas and Vidal-Meliá2014), the calculation of the accumulated capital at retirement age with both inclusion and non-inclusion of the survivor dividend is described in Appendix A. In particular, see equations (A.1) and (A.2) for technical details about the calculation of the accumulated notional capital with and without the inclusion of the survivor dividend.

• • Annuity divisors

In this paper, we study two different types of annuity divisor. First, in Appendix A, we describe the demographic divisor that takes into account the remaining future lifetime at retirement (equation A.4). In practice, the annuity divisors are equal for both genders, being based on unisex life tables for that cohort.Footnote ⁷ Second, the Swedish NDC scheme is the only one where the economic divisor is applied to calculate the pension liability of retirees. For the calculation of the economic annuity divisor, both the size of pensions and the pay-out period are considered rather than the number of people who are surviving. The mathematical formula for the economic divisor associated with the expected number of years of pension disbursements is expressed in equation (A.5) of Appendix A.

• • Calculation of divisors: an example with four periods

This section presents a simple illustration of the calculation of the demographic and economic divisor for a cohort that joins the labour market at age 0. In this model, the demographic-financial structure over time for this cohort is given by:

1. (1) Age:

   $$ \hskip -6pc \overbrace{{0, \;\,1, \;}}^{{{\rm Contributors^{\prime}\;ages}}}\underbrace{{2, \;\,3}}_{{{\rm Pensioners^{\prime}\;ages}}}.$$

2. (2) The number of individuals at age 0 is 100. Unisex probability of survival at retirement age (i.e., age 2) is 1 while the probability of survival to age 3 is 0.5. All individuals are dead by age 4.

3. (3) Average salary is constant and given by 100 monetary units. Contribution rate is equal to 10% of salary.

4. (4) For simplicity, we assume that the notional rate, the indexation rate of pensions and the discount rate are equal to zero.

Under this setting, the total accumulated notional capital for all individuals at retirement age is equal to 20 and the unisex demographic annuity divisor is equal to 1.5.Footnote ⁸ Consequently, the average pension per individual equals to 13.33.

In practice, salaries and probabilities of survival are different among populations. We assume that the average salary for women is equal to 5 with a probability of survival to age 3 of 0.6 while the average salary for men is 15 with a probability of survival to age 3 of 0.4. Also, we assume the proportions of men and women in the population are equal. In this case, the accumulated salary per man (woman) is 30 (10) while the amount of the pension using the unisex annuity divisor is 20 (6.67).

The economic divisor considers both differences in pension level and the composition of the population. In the economic divisor calculation, the probabilities of survival are weighted by the pension disbursements so this divisor represents the expected number of years of pension payments, i.e., 1.45.Footnote ⁹ The amount of the pension would then increase for both men and women if the economic divisor is used. If the probability of survival for women (men) is 0.4 (0.6), the value of the economic divisor would be 1.55. Consequently, we can see that the composition of the population has an impact on the value of the divisor and on the amount of the pension paid to the individuals. With no differences in pension levels and in the composition of population among groups, both divisors should be equal.

3. Modelling and forecasting mortality heterogeneity across socioeconomic groups

Some studies have applied survival models under different mortality laws (e.g., Gompertz, Makeham, Perks and Makeham-Perks, etc.) and generalised linear models to assess the level of mortality differentials but ignoring mortality improvement by socioeconomic profiles and projection of their future evolution.Footnote ¹⁰ When projecting the heterogeneity in mortality between socioeconomic groups (e.g., income, occupation or level of education), we need models that enable the capturing of both differentials in mortality levels and in mortality improvements between subpopulations.

Several papers have used multiple population extensions of the Lee–Carter Model (Lee and Carter, Reference Lee and Carter1992) which allow mortality modelling and forecasting for two or more related populations simultaneously. For instance, some papers study the quantification of mortality differentials across countries (Li and Lee, Reference Li and Lee2005; Li and Hardy, Reference Li and Hardy2011; Enchev et al., Reference Enchev, Kleinow and Cairns2017), regions within a country (Debón et al., Reference Debón, Montes and Martínez-Ruiz2011; Danesi et al., Reference Danesi, Haberman and Millossovich2015) or socioeconomic subgroups (Villegas and Haberman, Reference Villegas and Haberman2014; van Baal et al., Reference van Baal, Peters, Mackenbach and Nusselder2016).

The Joint-K model proposed by Carter and Lee (Reference Carter and Lee1992) assumes that mortality rates of all subpopulations are jointly driven by a single period index but the age-specific mortality pattern and the age-specific responses to changes in the level of mortality are subgroup-specific. Additionally, Villegas and Haberman (Reference Villegas and Haberman2014) have introduced a relative modelling approach where the mortality of socioeconomic subgroups is modelled relative to the mortality of a larger reference population – generally referred to the national population. Their finding concludes that mortality level differentials have a stronger impact on expectations of life and annuity values than mortality improvement differentials.

In this paper, we employ the extension of the Lee–Carter model, known as the ‘stratified Lee–Carter’ model proposed by Debón et al. (Reference Debón, Montes and Martínez-Ruiz2011) to estimate and forecast age- and gender-specific mortality rates across three levels of education. This model works even with small data sets.Footnote ¹¹ The model assumes that all subpopulations have the same mortality improvements at all times, described by the common factor β _x and K _t. In practice, it is unlikely that all subgroups would have the identical tendency; however, the assumption that related populations share a common time trend is the long run is reasonable when the available mortality statistics by educational attainment are limited.

The stratified Lee–Carter model proposed by Debón et al. (Reference Debón, Montes and Martínez-Ruiz2011) can be transformed into the relative modelling approach associated with the reference (national) population and the subpopulation introduced by Haberman et al. (Reference Haberman, Kaishev, Millossovich, Villegas, Baxter, Gaches, Gunnlaugsson and Sison2014).

The mortality of the reference population following the Lee–Carter model can be expressed as follows:

(2)$$\log m_{x, t} = \alpha _x + \beta _xK_t + \varepsilon _{x, t}, \;$$

where the central mortality rate at age x in calendar year t for the reference population, m _x,t, is computed as m _x,t = D _x,t/E _x,t. We denote D _x,t as the number of deaths of the reference population aged x who die in year t before they reach age x + 1 and the number of person-years of exposure to risk, E _x,t, is estimated by the mid-year population at age x in calendar year t, equivalently to the average number of individuals aged x over a year. The parameter α _x describes the average age-specific mortality pattern. The variable K _t is a time-varying mortality index representing the overall change in the level of mortality in year t and β _x measures deviation of the age-specific mortality level when the time index K _t changes.

Given the reference population model and the ‘stratified Lee–Carter’ model with the same parameter β _x and K _t for all populations, the mortality level differences of the subpopulation i compared to the reference population for age group x can be determined in the form of $\alpha _x^i$ as follows:

(3)$$\log m_{x, t}^i -\log m_{x, t} = \alpha _x^i .$$

Using equation (2), the mortality of the subpopulation i can be specified throughFootnote ¹²

(4)$$\log m_{x, t}^i = \alpha _x + \alpha _x^i + \beta _xK_t$$

with constraints $\sum\nolimits_{x\in X} {\beta _x} = 1$, $\sum\nolimits_{t\in T} {K_t} = 0$ and $\sum\nolimits_{i\in I} {\alpha _x^i } = 0$ for all x ∈ X where $m_{x, t}^i$ is the central mortality rate at age x, x ∈ X: = {x ₁, …, x _k}, in calendar year t, t ∈ T: = {t ₁, …, t _n}, for subpopulation i, i ∈ I: = {i ₁, …, i _s}, and $m_{x, t}^i = {{D_{x, t}^i } / {E_{x, t}^i }}$. The age-specific mortality level in subgroup i is $\alpha _x + \alpha _x^i$. The parameter β _x represents the age-specific pattern of mortality change for all subpopulations and K _t is a single-period index driving the mortality trend for all subpopulations. Also, the subgroup i is L for low education, M for medium education and H for high education, respectively. In Appendix B, we present the procedure and technical details for the estimation and projections of the group-specific mortality rates and the construction of the cohort life tables.

4. Measurement of income redistribution

Under NDC pension schemes, the amount of the pension depends on the accumulated notional capital together with the return it generates over the contributor's working life. Therefore, NDCs narrow the ratio between benefits and contributions, achieving greater actuarial fairness than the traditional defined benefit schemes. Participants who have paid the same amount of contributions and retire at the same age should be entitled to the same pension benefits, while individuals with longer earnings histories or higher earnings who have been contributing more will receive higher benefits.

A pension scheme is viewed as actuarially fair to an individual (or a group of individuals) with average mortality if the (expected) present value of lifetime contributions for this individual (or group of individuals) is equal to the (expected) present value of pension benefits.

Boado-Penas and Vidal-Meliá (Reference Boado-Penas and Vidal-Meliá2014) and Alonso-García et al. (Reference Alonso-García, Boado-Penas and Devolder2018) have demonstrated that the NDC scheme considering the survivor dividend is actuarially fair – pension rights are equivalent to contributions actually paid – on a cohort basis when the population is closed. Due to heterogeneity in mortality across the population, the use of unisex life expectancy as one factor of the actuarial divisor would introduce explicit income redistribution from high-mortality risk to low-mortality risk groups within the same generation (also known as an intra-generational redistribution). People who expect to live longer would get a higher return of the pension system than those who are expected to die earlier, given that they receive the same amount of initial pension at the same retirement age.

The measurement of lifetime redistribution from an individual's perspective can be investigated through the difference between an individual's lifetime contributions and lifetime retirement benefits – in this way, we would capture the money's worth of participation in the pension system (Börsch-Supan and Reil-Held, Reference Börsch-Supan and Reil-Held2001; Bonenkamp, Reference Bonenkamp2009; Belloni and Maccheroni, Reference Belloni and Maccheroni2013). However, we use a variant based on the principle of relative equivalence, called the benefit to cost ratio (or present value ratio) defined as the ratio between the present value of benefits paid during retirement and the contributions paid during their working career (Brown, Reference Brown, Feldstein and Liebman2002, Reference Brown2003; Liebman, Reference Liebman, Feldstein and Liebman2002; Borella and Coda Moscarola, Reference Borella and Coda Moscarola2006; Barnay, Reference Barnay2007; Mazzaferro et al., Reference Mazzaferro, Morciano and Savegnago2012; Belloni and Maccheroni, Reference Belloni and Maccheroni2013). Thus, the ratio shows how much the benefit system returns to the participant for each Euro paid.

A value of one indicates that the system is actuarially fair for an individual (i.e., she receives pension benefits which correspond to her contributions) – by definition, there is no redistribution towards or away from any person (Queisser and Whitehouse, Reference Queisser and Whitehouse2006). A value greater (lower) than one indicates that an individual receives more (less) than she has been contributing – an individual faces an expected gain (loss) from the pension system.

The present value ratio (henceforth PVR) for a specific individual, with gender i and level of education j, who pays scheme contributions for n years throughout the working life and receives pension benefits $P_{( {x_e + n + k, t + n + k} ) }^{i, j}$ at any age x _e + n + k in year t + n + k for m years from retirement age until the maximum age of surviving, is evaluated at the age of entry into the labour market x _e in year t and is expressed as

(5)$$PVR_{( {x_e, t} ) }^{i, j} = \displaystyle{{\sum\limits_{k = 0}^{m-1} {{}_{n + k}p_{( {x_e, t} ) }^{i, j} \cdot P_{( {x_e + n + k, t + n + k} ) }^{i, j} \cdot \prod\limits_{h = 0}^{n + k-1} {{( {1 + r_{t + h}^\ast } ) }^{-1}} } } \over {{}_0p_{x_e, t}^{i, j} \cdot \pi \cdot s_{( {x_e, t} ) }^{i, j} + \sum\limits_{k = 1}^{n-1} {{}_kp_{( {x_e, t} ) }^{i, j} \cdot \prod\limits_{h = 0}^{k-1} {{( {1 + r_{t + h}^\ast } ) }^{-1}} \cdot \pi \cdot s_{( {x_e + k, t + k} ) }^{i, j} } }}, \;$$

where ${}_kp_{( {x_e, t} ) }^{i, j}$ denotes the probability that an individual with gender i and level of education j, entering into the scheme at age x _e in year t will be surviving at age x _e + k in year t + k; $r_{t + h}^\ast$ is the real discount rate in year t + h and $\pi \cdot s_{( {x_e + k, t + k} ) }^{i, j}$ is the contribution paid in year t + k for an individual with gender i and education j at age x _e + k. The contribution is as a fixed fraction π of annual earnings (or salary) $s_{( {x_e + k, t + k} ) }^{i, j}$.

5. Numerical illustration

This section presents a numerical example based on the Swedish notional scheme to quantify the redistributive effects between subgroups within the same cohort when unisex divisors are used in the calculation of the initial pension. The sources of Swedish data for this illustration are discussed in the first sub-section while the results are presented in the second sub-section. We also provide a sensitivity analysis with respect to the underlying assumptions.

The Swedish notional scheme is particularly interesting for several reasons. First, as stated in Section 2, Sweden is the only country that distributes the survivor dividend among survivors of the same birth cohort. Our paper also analyses the effects of the survivor dividend on actuarial fairness between individuals belonging to different groups. Second, the Swedish NDC scheme is the only one where the economic divisor is computed to calculate the pension liability to retirees. With this in mind, our paper also analyses the effect of using an economic divisor on the pension amount and studies different possibilities for the design of an economic divisor.

5.1 Demographic and economic data and other assumptions related to the NDC scheme

In this subsection, we first describe the demographic and economic data and then other assumptions related to the NDC scheme.

5.1.1 Demographic and economic data

• • The participants in this study are classified by gender and three groups of educational attainment: low, medium and high level of education.Footnote ¹³ These persons have differences in terms of income profiles and survival probabilities which are the main factors for determining the direction and magnitude of the intra-generational transfers.

• • The cross-sectional average annual income for the Swedish population by age group, gender and level of education in 2013 provided in the Eurostat Database is used.Footnote ¹⁴ As shown in Figure 1, the pattern of age-earnings profile is an inverted U-shape where annual income increases in the early stages of a worker's career, peaks around middle-age and finally declines as a worker approaches retirement. Women earn less than men for all educational levels and the gender gap is wider for persons with high school education than for those with advanced degrees

• • The mortality data for this analysis consists of national mortality experience for calendar years 1960–2013 covering the age range 25–95 obtained from the Human Mortality Database (HMD), and the subpopulation dataset by educational attainment from Eurostat having a shorter observation period 2009–2013 with the age range 25–95. The set of calendar years of subpopulation data is a subset of the corresponding calendar years in the national population and the set of ages available within each subgroup is a subset of those available in the national population as well.

Figure 1. Age-earnings profile estimates during working life, age 25–69 by gender and level of education (in EUR).

Source: Authors' calculations derived from Eurostat Database (2017).

5.1.2 Choice of parameters and other assumptions related to the NDC scheme

In order to make the income redistribution comparable across subgroups, the main assumptions and the data sources used for this numerical example are as follows:

• • A participant joins the labour market at the age of x _e = 25 in 2013 with a particular level of education that does not change over her working life, and works continuously until retirement age.

• • The retirement age x _r is equal to 65. Therefore, a participant pays contributions for n = 40 years as no unemployment is considered.

• • The maximum age that an individual can survive is 95 so the pension benefits are disbursed for m = 31 years.Footnote ¹⁵

• • The contribution rate π is fixed at 16% of the individual's earnings.Footnote ¹⁶

• • The notional rate of return r, the discount rate credited in the annuity divisor r′, the discount rate for the PVR r* and the indexation rate λ to revalue the pension benefits are each set equal to 1.6% and are assumed to be constant over time.Footnote ¹⁷ In the case of the Swedish NDC scheme, both the notional accounts and benefits are indexed in line with changes in average income.Footnote ¹⁸ The system is front-loaded, i.e., benefits are calculated considering a discount rate of 1.6% in the annuity factor. Hence, the indexation of pensions is reduced during the pay-out time by subtracting 1.6% from the yearly income indexation.Footnote ¹⁹ However, in our calculations, we assume that the pensions are constant in real terms so that pensioners maintain their purchasing power. A sensitivity analysis of holding pensions constant in nominal terms is included in Table 6.

5.2 Results

In this subsection, we present the results of forecasting mortality per socioeconomic groups and discuss the main results in terms of income redistribution from using the demographic and economic divisors.

• • Forecasting mortality across socioeconomic groups

Statistics Sweden reported a period life expectancy at 65 in 2015 was 18.85 years for men and 21.39 years for women. During the last 10 years between 2006 and 2015, the period life expectancy for men has grown by 1.24 years, while the rise for women has been 0.68 years. There are also clear and growing differences in remaining life expectancy among education-specific groups. Specifically, remaining life expectancy at age 65 for males (females) with only compulsory education has increased from 17.02 (20.22) in 2006 to 18 (20.48) in 2015 while the increase from males (females) with a degree is equal to 1.55 (0.94) (The Statistics Sweden, 2016). Hence, in our analysis, the incorporation of group-specific mortality rates is important.

Figure 2 shows the estimated mortality rates in 2013 and projected rates in 2083 across subgroups by applying the ‘stratified Lee–Carter’ model.Footnote ²⁰ We can see that mortality across subgroups of males (females) is above (below) average mortality. Furthermore, Figure 2 shows that the average mortality rates for men and women are quite close to those with a medium level of education attainment and the mortality of men with high educational attainment and women with low attainment are almost equal to the rates for the overall population.

Figure 2. Evolution of mortality rates across gender and three levels of education.

Source: Authors' calculations derived from Human Mortality Database (2017).

By 2083, the age-specific mortality rates for all subgroups are projected to have continuously declined, while maintaining the existing patterns of mortality differentials. Also, because of the coherent approach to the modelling of mortality trends for subpopulations, independently for each gender, the projected future subgroup-specific mortality rates do not diverge in the long run and the education- and age-specific mortality rates for each gender deviate consistently from general (reference) mortality rates over time.

• • Application of the demographic annuity divisor

Under the conditions defined above, the unisex demographic annuity divisor for an individual aged 65 is equal to 24.2630 applying the equation (A.4). The values of this annuity divisor across subpopulations compared to the unisex annuity divisor are illustrated in Figure 3. It is noticeable that the values of the demographic divisors for all subgroups of women (men) are greater (lower) than the unisex. The values of the demographic annuity divisors across the subgroups have a pattern that is consistent with mortality.

Figure 3. Annuity divisors under the baseline assumptions by gender and education.

Source: Authors' calculations.

The money's worth of the pension benefit for an individual who retires at age 65, given the unisex annuity divisor at 24.2630, is measured through the PVR as exhibited in Figure 4. When the survivor dividend is included in the calculation of the initial pension and if there is no heterogeneity in mortality across populations, the PVR is equal to one indicating that the individuals will receive pension benefits identical to what they have contributed over their working lives.

Figure 4. PVR across subpopulations in the cases of notional capital including and excluding survivor dividend.

Source: Authors' calculations.

Considering differences in levels of mortality rates per groups, the PVR is higher for females than for males and it increases with the level of education attainment, ranging from 0.9024 for a low-educational attainment male to 1.1127 for a high-educated female worker. Moreover, it is worth noting that all subgroups of females benefit from the use of the unisex demographic divisor, i.e., the PVRs are higher than 1, as shown in Figure 4, which implies that they receive a pension transfer. However, the PVRs for most of the subgroups of males are less than 1, which implies that they pay for a pension transfer.

A low-educational attainment male worker is the largest loser, with a PVR of 0.9024 which is 4.96% less than the PVR for the average man and 9.76% less than the PVR for the average population, while a high-educational attainment male receives a transfer of income from the system of 1.54%.Footnote ²¹ In contrast, all women obtain gains when the unisex demographic annuity divisor is used (i.e., 1.35% of transfer for a woman with a low educational level, 6.99% for a medium educational level and 11.72% for a level of high education attainment).

If the unisex demographic divisor is used, it is remarkable that gender has a larger impact on income redistribution as, even for women with low educational attainment, the PVR is higher than the case for the average population.

In Figure 4, when the survivor dividend is not included in the calculation of the pension benefit, the PVR decreases by 4.37% for all subgroups. However, even without the inclusion of the survivor dividend, women – specifically with levels of medium and high education attainment – still benefit from the system with a PVR higher than one.Footnote ²²

• • Application of the economic annuity divisor

The value of the economic divisor for a particular cohort corresponding to equation (A.5) depends on the population composition. Therefore, some plausible assumptions for the size of the different subgroups are needed. As stated in Section 2, the value of the economic divisor increases when the pension disbursement is higher, and the pay-out period is longer.

Table 1 shows results when the number of females increases (decreases) by 20% with respect to the number of males (i.e., $l_{x_e + n}^{\,female} = 1.2l_{x_e + n}^{male}$ or $l_{x_e + n}^{\,female} = 0.8l_{x_e + n}^{male}$), keeping an equal composition by level of education, that is, one-third of the population for each level of education attainment. If we calculate the economic divisor only considering gender differences in mortality, we see that the value of the economic annuity (i.e., 24.4383) is higher than the demographic divisor when the number of women is larger since the number of years that pensions will be disbursed increases – women generally live longer than men. In contrast, when the number of women is smaller, the value of the economic divisor is lower than the demographic divisor.

Table 1. PVR for different subgroups when only gender differences in mortality taking into account in the calculation of the divisors

Source: Authors' calculations.

Consequently, as shown in Table 1, when the value of the economic divisor is higher (lower), both the amount of the pension and the PVR decrease (increase) compared to the case of using the unisex demographic annuity divisor.

The economic annuity divisor depends on the different sizes of the socioeconomic groups in the total population. In the case that all individuals have a low level of educational attainment, the value of the economic divisor is lower (i.e., 23.5324) than the unisex demographic divisor, as illustrated in Table 2. The use of this economic divisor, which assumes that all individuals have low level of educational attainment, would provide a higher initial pension and consequently all subgroups would benefit from the application of the economic divisor. Conversely, the value of the economic divisor increases when its calculation assumes that all individuals have high level of educational attainment and thus the PVRs for all subpopulations decrease by 4.38% compared to the case of using the demographic annuity divisor.

Table 2. PVR for different subgroups when all individuals are considered to have the same education level (low, medium or high education) for the calculation of the economic divisor

Source: Authors' calculations.

Table 3 extends Table 2 and assumes six different compositions of the population when calculating the economic divisor.Footnote ²³ As shown in Table 3, the values of the economic divisor increase with a high level of educational attainment in the population. Specifically, the lowest value of the economic divisor (i.e., 23.9604) results from a combination of males with medium educational attainment and females with low attainment. The values of the economic divisors increase with the level of education and we can categorise the results into three groups depending on the combination of population structure: level of low and medium education (23.9604 and 24.0983), the low and high education (24.5034 and 24.6203), and the medium and high education (24.9382 and 24.9489), respectively.

Table 3. PVR for different subgroups when six different combinations of population are considered for the calculation of the economic divisor

Source: Authors' calculations.

Note: (1) ML&WM – all men are low-educated and all women are medium-educated; (2) ML&WH – all men are low-educated and all women are high-educated; (3) MM&WL – all men are medium-educated and all women are low-educated; (4) MM&WH – all men are medium-educated and all women are high-educated; (5) MH&WL – all men are high-educated and all women are low-educated; (6) MH&WM – all men are high-educated and all women are medium-educated.

Furthermore, we show that there are slight differences in the economic divisor values when the population consists of the same combination of levels of educational attainment regardless of gender. For example, the value of the economic divisor for the case of a population consisting of males with high educational attainment and females with low attainment, 24.5034, is quite similar to the case of males with a low attainment and females with a high level, 24.6203. With the same combination of education, the value of the economic divisor is lower for the case where women have a lower level of education than men due to their longer life expectancy.

Notably, a lower value of the economic divisor produces a higher initial pension and it leads to higher values of PVR for all subgroups and vice versa. Although the values of economic divisors vary depending on the population structure, females with medium and high educational attainment benefit from the system no matter which assumptions are used to calculate the divisor.

5.3 Sensitivity analysis

This section presents a sensitivity analysis of some variables that might affect the redistribution of the NDC scheme such as the retirement age, notional rate, discount rate and indexation of pensions in payment. A comparative statics framework is used, changing a single variable at a time. The results are illustrated only for the case of the unisex demographic divisor.Footnote ²⁴

• • Changes in retirement age

As seen in equations (A.1), (A.2) and (A.4), when the retirement age increases, the accumulated notional capital increases and the demographic annuity divisor decreases due to a shorter remaining life expectancy. As a result, the amount of the initial pension increases but the effect on the PVR is not clear. When the survivor dividend is not distributed, the PVR would decrease if the retirement age increases (see Figure 5b).

Figure 5. PVR when using unisex demographic divisor with different retirement ages in the case of including and excluding survivor dividend.

Source: Authors' calculations.

Note: Results are based on the main assumptions, but retirement ages vary between 61 and 70.

Surprisingly, when the survivor dividend is considered (Figure 5a), the PVRs for all subgroups of females increase with retirement age due to the higher value of the notional capital after the inclusion of the dividend. For males, we can see that the higher values of the accumulated balances – resulting in higher pensions – do not compensate for the shorter lifespan associated with a later retirement and therefore the PVRs decrease when the retirement age increases.

• • Changes in notional rate of return

Changes in the notional rate of return have a positive effect on the amount of the accumulated notional capital at retirement age and, as a result, on the direct change in the amount of the initial pension. The expected present value of pension benefits would also increase when the notional rate increases, while the expected present value of contribution payments remains unchanged. Consequently, the PVRs increase with (almost) the same percentage for all subgroups as shown in Table 4 and the results will be more favourable in terms of actuarial gains.

• • Changes in discount rate

A higher discount rate will reduce the value of demographic annuity divisors and both the expected present value of contribution payments and pension benefits would decrease. This would lead to the reduction in the PVRs as exhibited in Table 5. The changes in the discount rate have a relatively larger effect on the pension rights of females than males and the same happens for individuals with high educational attainment relative to those with lower levels.

Table 5. PVR with different discount rates and % relative change compared to the case of using demographic divisor under the main assumptions with 1.6% discount rate

Source: Authors' calculations.

When the discount rate increases to 2%, the cross-gender redistribution declines by 7.97% for males and by 8.33% for females and, considering the subgroups among the female population, the PVR drops by 8.30% for individuals with low-educational attainment and 8.41% for the ones with high levels. Therefore, an increase in the rate of discount brings about a greater loss for all subgroups of the population.

• • Changes in indexation rate

We finally present the distributional effects if we change the rate of indexation used to adjust the amount of pension benefits in each year. A higher indexation rate gives higher values for the annuity divisor and, therefore, the amount of the initial pension would be lower. In particular, in the case that there is no indexation – the pension benefits remain constant over time – the unisex annuity divisor decreases from 24.2630 to 19.9924 as illustrated in Table 6.

Table 4. PVR with different notional rates and % of relative change compared to the case of using demographic divisor under the main assumptions with 1.6% of notional rate

Source: Authors' calculations.

Table 6. PVR with different indexation rates and % relative change compared to the case of using demographic divisor under the main assumptions with 1.6% of indexation rate

Source: Authors' calculations.

However, we show that the PVRs do not change in the same direction for males and females (i.e., PVRs decrease for males and increase for women when the rate of indexation of pension increases). This is due to the fact that the expected present value of pensions for women increases with increases in the value of the indexation rate since this group benefits from having a longer life expectancy than average.