Democracy

We studied three time-series country-level indicators from independent datasets that capture different aspects of democracy. Polity 5 (Marshall et al., Reference Marshall, Jaggers and Gurr2019) measures nations’ autocratic or democratic character, emphasising restraints on executive functions, and covers the period 1800–2020. We used the revised combined polity2 measure, which ranges from −10 (autocracy) to 10 (democracy). Vanhanen's Index of Democracy from the Polyarchy dataset (Vanhanen, Reference Vanhanen2000) measures nations’ electoral participation and competition over the years 1810–2012. The index ranges from 0 (no participation/competition) to 50 (full participation/competition). Freedom House's Freedom in the World survey (FH) (Freedom House, 2021) measures individual rights and freedoms in nations over the period 1972–2020. We used the combined reversed score which ranges from 0 (not free) to 12 (free).

Democracy data were aggregated in the statistical software R (R Core Team, 2020) using the package democracyData (Márquez, Reference Márquez2017). Data from later years not covered by the package were added manually. Pearson's correlation between Polity and the Vanhanen Index across all years was 0.76, between Polity and FH 0.89, and between Vanhanen and FH 0.82, all significant at a level of p < 0.001.

Country sample

We sampled all years for all UN member states and all historical nations represented in the three democracy datasets. This resulted in a list of 221 modern and historical nations (see Table S1), spanning a period of 220 years across three democracy outcomes and 41,638 observations in total. Data availability and therefore nations sampled by year varied over time, from just 25–50 nations (covering all continents, including Asia, North and South America, Africa, and Europe) at the beginning of the nineteenth century to 160–200 nations in the twenty-first century (see Figure 1; note that the Freedom House data only begin in 1972). This shift in sample size reflects both less source data available on nations earlier in the time series and a real increase in the number of internationally recognised sovereign states around the globe (since the establishment of the UN in 1945, the number of recognised member states has increased from 51 to 193 today, including but not restricted to new sovereign states associated with decolonisation and the fall of communism). Figure 2 shows the global distribution of Polity 5 scores across linguistic and religious networks of 163 contemporary nations (see Figures S1–2 for similar plots of Vanhanen and Freedom House data).

We note that nations that amalgamate or split up are treated as separate entities by the Polity 5, Vanhanen, and Freedom House datasets, and given different country codes. For example, Korea (KOR) ceased to exist in 1945 when South Korea (KR) and North Korea (KP) were established. We used the same system, treating these as three separate nations with their own location and cultural affiliation data. This has no effect on our cross-sectional analyses because we are only interested in democratic similarity between nations that existed in any given year. In the longitudinal analyses, since we predict a nation's democracy score at Time 2 (T2) from the democracy score of its geographical and cultural neighbours at Time 1 (T1), controlling for its own democracy at T1, we only track democratic change in countries that were in existence at T1 and T2, and the effects we describe therefore relate to internal change within established nations, rather than transitions associated with the amalgamation or the splitting of nations.

Cultural connections

We quantified two measures of cultural connections between nations in our sample, linguistic and religious (see Figure 2), based on the methodology outlined in Eff (Reference Eff2008). First, we used known ancestral relationships between all languages and between all religions to calculate pairwise cultural similarity scores between them (see the next sections for details on these calculations). We then used these scores to derive pairwise linguistic and religious connection measures between all nations. Our linguistic connection measure considered the cultural similarity of all languages spoken by at least 1 permille of the population in any pair of nations, weighted by respective speaker percentages in each nation, as recorded in Ethnologue 21 (Eberhard et al., Reference Eberhard, Simons and Fennig2018). We repeated the same process for religion, by comparing the ancestral relationships of 28 major religions across all nations (Figure S3), weighted by respective adherent percentages from National Profiles (Finke & Grim, Reference Finke and Grim2019) of the Association of Religion Data Archives (ARDA; Brown et al., Reference Brown, Mataic, Bader and Finke2018). We ignored ARDA's ‘other’ and ‘syncretic’ religions, as well as ‘neoreligionism’ and ‘atheism’, because they represent broad categories that do not necessarily imply common ancestry. For historical states we made approximate estimates for percentages based on the CIA factbook (Central Intelligence Agency, 2018) archives as well as other sources (Bjørklund, Reference Bjørklund1970; Izady, Reference Izady2018; Joshua Project, 2018; McNally et al., Reference McNally1893; Smiley, Reference Smiley1839; Statistics Canada, 2009; Wittman, Reference Wittman1907). The linguistic or religious connection c_rk between two nations r and k was thus defined as (1):

(1)$$c_{rk} = \mathop \sum \limits_i \;\mathop \sum \limits_j p_{ik}\;p_{\,jr}\;s_{ij}$$

where p_ik is the percentage of the population in nation k speaking language i (or adhering to religion i), p_jr is the percentage of the population in nation r speaking language j (or adhering to religion j) and s_ij is the proximity measure between languages i and j (or religions i and j). The following two sections explain how values s_ij were calculated for linguistic and religious data.

Language ancestry

Quantifying linguistic ties between nations required a measure of genealogical relationships between languages themselves. To this end, we compiled a global language tree of all ~7000 languages based on genealogical assignments specified in Glottolog 3.0 (Hammerström et al., Reference Hammerström, Forkel and Haspelmath2018). After removing unattested, unclassified or pidgin languages, as well as dialects, we acquired a single unrooted, unresolved language tree with 7186 languages. To generate branch lengths and produce an ultrametric global language family tree, we used Grafen's method (Grafen, Reference Grafen1989), which assigns each node a height value based on the number of leaves in the subtree minus 1, scales the values so that the root height is 1 and the height of leaves is 0, and raises them to the power ‘rho’ (> 0). The difference in these values between a node and its parent is their branch length. Tree manipulation took place in R using the compute.brlen and the cophenetic.phylo functions of the R package ape (Paradis et al., Reference Paradis, Claude and Strimmer2004). This resulted in a 7186 × 7186 matrix of pairwise distances between all languages; values were reversed to proximities and used as s_ij in equation (1) above.

Religion ancestry

We constructed a family tree showing genealogical relationships between 28 religious lineages (Figure S3), informed by historical sources and key historical events and dates (see Supplementary Materials). To account for evidence of horizontal transmission between some traditions, rather than a single tree, we derived a sample of eight religion trees in which the alternative paths of inheritance represented by the different horizontal transmission events are captured by different bifurcating combinations of splits that alter tip-to-tip distances. The small number of broadly defined religious traditions we considered (28 as compared with ~7000 languages) meant that it was feasible to use historical information to date the age of most of the traditions, and the hybridisation events. While the precise chronology of the tree is contestable, we judged some approximation of time depth preferable to not attempting to include historical information in branch lengths. Moreover, as we show in our robustness checks, using alternative branch lengths that do not include time–depth information produces qualitatively similar results. We extracted the pairwise distance matrices from each tree, and then averaged them to produce a working model for this analysis. Paths that did not involve horizontal transmission were unaffected by this procedure, while paths that crossed a horizontal transmission event are the mean value of the alternative pathways represented by that event. This religion tree can be seen in Figure S3. The resulting 28 × 28 matrix captured pairwise distances between these religions; values were reversed to proximities and used as s_ij in equation (1) above.

Geographic proximity

In order to control for geographical relations between nations, our analyses included a geographical proximity matrix. We assigned each nation the point location of its capital city, since the population bulk in a nation is typically gathered in and around its capital. We obtained coordinates for capitals of the countries in our sample using the R package maps (Deckmyn, Reference Deckmyn2018) and Google Maps, and calculated pairwise geodesic distances, which accounts for the Earth's ellipsoid shape, using the distGeo function of the R package geosphere (Hijmans et al., Reference Hijmans, Williams, Vennes and Hijmans2017). Following convention, we log-transformed geographical distance by calculating its logarithm in base 10. Values could be reversed to proximity or distance accordingly.

Cross-sectional analysis

For our cross-sectional analyses we used a dyadic regression approach with random effects (Karimov & Matthews, Reference Karimov and Matthews2017). This approach differs from standard linear regression in that all predictor and outcome variables represent pairwise (dyadic) differences rather than monadic values. The lower triangles of symmetric distance matrices, i.e. undirected networks where the distance from node A to B is the same as the distance from B to A, can be converted to vectors of pairwise differences that are then regressed using linear regression. Although the end result is a vector, it is still based on matrix data, as values represent distances between data points, rather than independent scores. In order to control for the repetition of cases, the identities of each node in the pair are added as random effects. The dyadic regression with random effects approach was initially developed in the context of longitudinal social network analyses by de Nooy (Reference De Nooy2011) and O'Malley and Christakis (Reference O'malley and Christakis2011), who also offer mathematical proofs of the validity of the approach. Simulations also indicate that dyadic regression with random effects outperforms alternative autoregressive models for the type of data we consider here (Karimov & Matthews, Reference Karimov and Matthews2017).

For each of the three democracy indicators, we predicted pairwise differences in democracy between nations from their linguistic, religious and geographical connections. Data for each year for each of the three indicators constituted a separate analysis. First, we converted democracy scores for each year to a matrix of between-country differences in democracy. We also subset our three predictors, pairwise linguistic, religious and geographical connections, to include the same nations as the democracy matrix for each year. We standardised all dependent and independent variables by dividing values by their standard deviation to overcome scaling and interpretability issues, and extracted their lower triangles (since all matrices were symmetrical). Then we regressed the dependent variable on our predictors, including nation identities as random effects. The full model including linguistic, religious and geographical connections between nations can be expressed as follows:

(2)$$dem.diff\sim ling.con + rel.con + geo.prox + ( {1 \vert id_i} ) + ( {1 \vert id_j} ) $$

where dem.diff represents pairwise difference in democracy between pairs of nations, ling.con represents the nations’ linguistic connections, rel.con represents their religious connections, geo.prox is their geographical proximity and (1|id_i) and (1|id_j) are the random effects for the repeated identities of the nodes on each end of the dyadic relationship. We analysed all years available for each democracy measure (Freedom House, 1972–2020; Polity 5, 1800–2018; Vanhanen Index, 1810–2012), resulting in 466 cross-sectional analyses (Figure 3).

Figure 3. Independent effects of geographical, linguistic and religious connections predicting democracy. Pairwise differences in democracy between nations were simultaneously regressed on geographical, linguistic and religious connections between nations, at each time slice for which data was available, resulting in 466 cross-sectional models. Multiple regression standardised coefficients of the three predictors are presented separately for Polity 5 (a, 1800–2018), the Vanhanen Index (b, 1810–2012) and Freedom House data (c, 1972–2020), with 95% CI annotated. The direction and significance of effects are colour-coded: red for significant positive coefficients (p < 0.05), pink for non-significant positive coefficients, dark blue for significant negative coefficients (p < 0.05) and light blue for non-significant negative coefficients. (d–f) Semi-partial coefficients of determination (R ²) are displayed below the respective models and outcome variables from (a–c), indicating the proportion of variance in democracy explained by geography (green), language (red) or religion (blue), after controlling for the other two variables. The three waves of democratisation are highlighted in grey on all graphs.

Statistical analysis was performed in R using the lmer function of the lme4 package (Paradis et al., Reference Paradis, Claude and Strimmer2004). All statistical tests reported are two-sided.

Contiguity

In order to control for simple contiguity (adjacency) effects, rather than effects of weighted cultural or geographical connections, we also constructed three contiguity matrices. Pairs of nations sharing a land or river border, the same majority language or the same majority religion were assigned a value of 1, and 0 in all other cases, leading to binary measures. For robustness checks, we repeated cross-sectional analyses adding to our models one contiguity matrix at a time (Figures S4–6).

Longitudinal analysis

For each of the three democracy indicators, we predicted nations’ democracy scores at T2 from the weighted cumulative democracy score of their cultural relatives or geographical neighbours at T1, controlling for each nation's democracy at T1.

For this analysis we calculated three new predictor variables representing the weighted cumulative democracy of each nation's cultural and geographical neighbours at T1, as indicated by the linguistic, religious and geographical connection matrices. We multiplied each connection between a focal nation (a row in the matrix) and its neighbours (columns) with the democracy scores of the focal nation's neighbours at T1, and summed rows. These row sums gave an estimate of the cumulative democracy of a focal country's neighbours, weighted by their linguistic, religious or geographical proximity. The model can be expressed as follows:

(3)$$dem_{T2}\sim dem_{T1} + dem.ling.relatives_{T1} + dem.rel.relatives_{T1} + dem.geo.neighbours_{T1} $$

where dem_T2 and dem_T1 are the democracy scores at T2 and T1 respectively; dem.ling.relatives_T1 is the cumulative democracy of linguistic relatives at T1, weighted by respective linguistic connections; dem.rel.relatives_T1 is the cumulative democracy of religious relatives at T1, weighted by respective religious connections; dem.geo.neighbours_T1 is the cumulative democracy of geographical neighbours at T1, weighted by respective geographical proximities.

The appropriate time lag (separating T1 and T2) depends on the level of year-on-year variation in the democracy values and probable speed with which values are likely to spread between nations. We report findings based on a 10-year lag but also ran shorter (5 year) and longer (20 year) lags as robustness checks (see Figures S7–8). Lags smaller than 5 years were too highly correlated with the outcome variable (democracy at T2) and as a result caused model convergence issues.

Explained variance

Although estimating coefficients of determination (R ²) in mixed models is challenging, they can give a good general indication of the magnitude of an observed relation independent of sample size and complement significance testing (Selya et al., Reference Selya, Rose, Dierker, Hedeker and Mermelstein2012). To estimate the explained variance, we calculated semi-partial coefficients of determination for each fixed effect after removing the variance explained by other predictors using the r2beta function of the r2glmm package (Jaeger, Reference Jaeger2017). We relied on the Nakagawa approach (Nakagawa et al., Reference Nakagawa, Johnson and Schielzeth2017), which is appropriate for data of this structure.

Alternative cultural connection measures

To evaluate the robustness of findings to choice of proximity metrics, we produced alternative versions of our cultural networks. We kept everything in our methodology constant, except for the way branch lengths in our language and religion trees, and consequently distances between languages and religions, were calculated. In our alternative approach, we set the branch lengths of the trees equal to 1 and then calculated relatedness between taxa using a patristic distance approach (Eff, Reference Eff2008). Hence, similarity s between languages i and j was set as the distance d (in number of edges) from their most recent common ancestor m to the root of the tree r, standardised by the height of the tree d_r, through the formula:

(4)$$s_{ij} = \displaystyle{{( {d_r-\;d_m} ) } \over {d_r}}$$

where d_r is the maximum path length (in number of edges) from any taxon to the root (tree height) and d_m is the maximum path length from any taxon to the most recent common ancestor m. Calculations were made in R using the packages ape (Paradis et al., Reference Paradis, Claude and Strimmer2004), phytools (Revell, Reference Revell2012) and phangorn (Schliep, Reference Schliep2011). This approach resulted in new measures s_ij for equation (1), producing two alternative matrices of linguistic and religious connections between nations.

Model selection using the corrected Akaike Information Criterion indicated that the connection measures used in our main analyses were always preferred over the alternative measures over the last ~50 years for which we have data on all three democracy measures and the largest sample of countries (1972–2020; see Figure S9). For periods prior to that, either the alternative networks were preferred or both models performed equally well. See the Supplementary Materials for results based on these networks.

Regression assumptions

In order to evaluate departures from the regression assumptions of homogeneity of variance and normality of residuals, we examined residual plots and quantile–quantile plots (Q–Q plots), sampling every five years, out of a pool of 893 core cross-sectional and longitudinal analyses (corresponding to the results in Figure 3 and 4) – see Figures S10–21. Regarding the cross-sectional analyses, the oblique, band-like distribution of fitted values against residuals is typical for discrete dependent variables (such as our differences in democracy indices), which have a hard upper and lower limit for values (Turchin, Reference Turchin2018). What matters is that values are centred around zero, which is largely confirmed across the bulk of the range of fitted values by locally weighted smoothing. The Q–Q plots indicate that the assumption of normality is met more clearly in some years compared with others, suggesting that some caution is necessary when interpreting these parameter estimates. Residual and Q–Q plots generally look better for the longitudinal analyses, although again, suggest some caution is necessary when interpreting these estimates. One approach to deal with these departures from normality would be to transform the data or fit regression models using different likelihood functions (e.g. beta or ordinal regression). However, because the observed departures from normality are variable in size and direction, this would require different transformations and/or likelihood functions across variables and years, undermining the comparability of parameter estimates across democracy indicators and time. Moreover, our results remain consistent across predictor variables, various transformations of the data and robustness checks, mitigating concerns about the sensitivity of our findings to specific violations of modelling assumptions. We have therefore opted to retain the Gaussian likelihood function, but present our residual and Q–Q plots for transparency.

Figure 4. Independent effects of democracy among geographical, linguistic, and religious connections at T1 predicting democracy at T2 (10 year lag). Nations’ democracy scores at T2 were simultaneously regressed on the cumulative democracy of their geographical, linguistic and religious connections at T1 (10 years prior), after controlling for their democracy at T1. These analyses essentially trace changes in democracy over a 10-year period based on democracy in neighbouring or related nations (see also Figure 2). Each time slice was analysed separately for each of the three democracy measures (see Methods), resulting in 426 longitudinal models. Multiple regression standardised coefficients of the three main predictors are presented separately for Polity 5 (a, 1810–2018), the Vanhanen Index (b, 1820–2012) and Freedom House data (c, 1982 –2020), with 95% CI annotated. The direction and significance of effects are colour-coded: red for significant positive coefficients (p < 0.05), pink for non-significant positive coefficients, dark blue for significant negative coefficients (p < 0.05) and light blue for non-significant negative coefficients. (d–f) Semi-partial coefficients of determination (R ²) are displayed below the respective models and outcome variables from a-c, indicating the proportion of variance in democracy explained by the cumulative democracy of geographical neighbours (green), and linguistic (red) or religious relatives (blue), after controlling for the other two variables and difference in democracy at T1. The three waves of democratisation are highlighted in grey on all graphs.