3.1 Climate anomalies: the SPEI

As our main climate indicator, we use the standardized precipitation-evapotranspiration index (SPEI) from the high-resolution ($0.5^\circ \times 0.5^\circ$) gridded dataset developed by Vicente-Serrano et al. (Reference Vicente-Serrano, Beguería and López-Moreno2010). Several other objective drought indices have been developed and used, such as the Palmer Drought Severity Index or the Standard Precipitation Index, but the SPEI has several advantages over them. In particular, it allows for comparison of drought severity through time and space whereas the Palmer Drought Severity Index does not, and considers both the role of temperature and precipitation variability, while the Standard Precipitation Index only considers the latter (Vicente-Serrano et al., Reference Vicente-Serrano, Beguería and López-Moreno2010).

As explained by Vicente-Serrano et al. (Reference Vicente-Serrano, Beguería and López-Moreno2010), taking into account temperature in addition to precipitation is crucial since the impact of rainfall on the growing cycle of a plant also depends on the ability of the soil to retain water. This is captured by “potential evapotranspiration”, which in turn depends on numerous parameters including surface temperature, air humidity, latitude, solar radiation and wind speed. The SPEI is calculated as the difference between monthly precipitation and the potential evapotranspiration, and has been shown to correlate better with hydrological and ecological variables than other drought indices in a variety of natural systems (Beguería et al., Reference Beguería, Vicente-Serrano, Reig and Latorre2014).

In terms of their interpretation, SPEI values represent standard deviations above or below historical SPEI values in a given location. This allows comparison of droughts across locations with very different climatology. To take a simple example, in absolute terms (millimeters of rain) a $-$1 drought in a Sahelian region will be very different from a $-$1 drought in a tropical forest region, but both situations are comparable because they represent the same degree of deviation from the normal conditions at each site, to which the natural vegetation of the area is adapted.

To account for different types of droughts, the SPEI is computed from different time scales. Short-time scales represent soil water content and discharge in headwaters, while medium-time scales refer to storage of water sources, and long-time scales illustrate variations in groundwater. To capture conditions that cause agricultural stress, we use the 12-month SPEI.Footnote ⁷

The intensity of a drought is measured according to the value of the SPEI. SPEI values ranging from 0 to $-0.99$ correspond to a mild drought; from $-1$ to $-1.49$ to a moderate drought; from $-1.5$ to $-1.99$ to a severe drought, while an extreme drought corresponds to a SPEI value below $-$2. An excess of precipitation can be measured following exactly the same logic, beginning with a value of $+$1. The average SPEI values for Mali at a time scale spanning 12 months are displayed in figure A2 (online appendix). The figure shows large fluctuations over the 1967–2009 period for all Malian agro-ecological zones, with a dominance of dry events. The standardized anomalies of precipitation, evapotranspiration and temperature are particularly intense in the years 1973–1974, 1982–1984 and 2002, with SPEI values during the growing season corresponding to severe droughts. Outside these sub-periods, averaged SPEI values are mostly negative, with a few exceptions. Given these patterns, our empirical analysis will mainly focus on dry events since there is no clear sign of excess precipitation over the period under concern, at least at the aggregate level.Footnote ⁸

For our empirical analysis, we create different variables to measure the number and magnitude of drought:

• • Number of dry years: We define a binary variable (by locality) that takes the value 1 if the average monthly value of SPEI in a given year is below the average monthly value of SPEI computed from 1904 to the year of the survey by more than one standard deviation, and 0 otherwise. We then compute the number of dry years for each intercensal period.

• • Number of dry agricultural seasons: We define a binary variable (by locality) that takes the value 1 if the average monthly value of SPEI during the agricultural season (from June to October) in a given year is below the average monthly value of SPEI from 1904 to the year of the survey by more than one standard deviation, and 0 otherwise. We then compute the number of dry agricultural seasons for each intercensal period.

Note that while these two variables will be mostly used in our regressions, we will also turn to other climate indicators, such as the number of intense dry years, translating into averaged SPEI values that are below the long-term average by more than 1.5 standard deviations, the number of dry years in respectively the first five years of the intercensal period and the last five years, and so on.Footnote ⁹ Figure A3 in the online appendix displays the number of dry agricultural seasons for each intercensal period and each Malian municipality. As is made clear from the comparison of the different periods, the 1977–1987 period was on average much dryer than the two subsequent ones. As a result, drought frequency is lower in the 1990s and even more so in the 2000s, which correspond to our two periods of analysis.

3.2 Measuring migration through the Malian population censuses

District-level migration data is not available from any secondary source or population register. We thus estimate net migration rates using three rounds of population censuses (1987, 1998 and 2009) and international emigration rates using the 2009 census.Footnote ¹⁰ The method used to compute our migration indicators by age cohort and sex, together with an assessment of their strengths and weaknesses, are detailed in online appendix B.

4.1 Empirical strategy

We first estimate regressions of the number of dry years on migration, using standardized net migration rates for different age-cohorts (net migration rates are standardized using their across-locality mean and standard deviation in order to make comparisons between regression coefficients across models easier).Footnote ¹¹ All regressions are panel regressions with locality and period fixed-effects. Since we expect climate to have differentiated effects on rural and urban localities, we systematically interact our drought variable with a dummy taking the value 1 if the locality is urban. Equations whose estimation results are shown in tables 1 and A3 (online appendix) are of the following type:

(1)\begin{align} NMR_{j,a,[t-11,t]}=\beta _{0}+\beta _{1}\sum_{i=0}^{11}drought_{j,t-i}+\beta _{2}\sum_{i=0}^{11}drought_{j,t-i}\ast Urban+\delta _{j}+\delta _{t}+\epsilon _{j,t}.\end{align}

$NMR_{j,a,[t-11,t]}$ is inter-census net migration rate at the locality level, where j, a and t refer to age-cohort, locality and inter-census period, respectively. $\sum _{i=0}^{11}drought_{j,t-i}$ is the number of dry years (or dry agricultural seasons) over the intercensal period; Urban is a dummy taking the value one if the locality is classified as urban in the census, zero otherwise; $\delta _{j}$ and $\delta _{t}$ are locality and period fixed effects respectively and $\epsilon _{j,t}$ is an error term. The locality fixed effects reduce the potential of omitted variable bias driving the estimated coefficients on our shock variable. Their inclusion in the model is particularly important given limitations in data availability, which restrict us from including variables that may be correlated both with climate and migration. The inclusion of period fixed effects allows us to control for path dependency of localities with historically and structurally high rates of emigration for reasons that may be climate-related or not.

Table 1. Drought effects on standardized net migration rates

Sample: Census from 1987, 1998 and 2009. Notes: Standard errors in parentheses corrected for serial correlation over one period and for spatial correlation up to a distance cutoff at 500 km. Std. Dev. corresponds to the standard deviation of net migration rates.

We estimate equation (1) following the procedure of Hsiang (Reference Hsiang2010) based on Conley (Reference Conley1999) to adjust standard errors for both spatial and serial correlation.Footnote ¹² In some specifications, we will also include a full set of region-by-period fixed effects, to adjust for all factors that are common across localities within a region by period, such as agricultural prices. District-by-period fixed effects, or even municipality-by-period fixed effects would have been even more appropriate, but a concern with the use of these interacted terms is that they absorb a significant amount of weather variance.

To illustrate this, table A1 (in the online appendix) summarizes regressions of SPEI values on various sets of fixed effects (period fixed effects only; locality plus period fixed effects; locality plus period plus district-by-period fixed effects and locality plus period plus municipality-by-period fixed effectsFootnote ¹³ ) and how much variation they absorb. On the first line are reported the R-square values of the different regressions. As suggested by the figures, district-by-period and municipality-by-period fixed effects absorb almost all variation. As a result, introducing these interaction terms in equation (1) means that the identification of climate effects would rest on very slim margins. This is also true for region-by-period fixed effects, but to a lesser extent.

As an alternative, we adopt the Interactive Fixed Effect estimator, a flexible linear factor model developed by Bai (Reference Bai2009), and discussed by Totty (Reference Totty2017). Contrary to the OLS estimate that assumes an idiosyncratic error term, the factor model allows the error term to be composed of unobserved common factors correlated with the regressors:

(2)\begin{equation} \epsilon _{j,t}=\lambda _{j}^{\prime }F_{t}+\mu _{j,t}.\end{equation}

$F_{t}$ is a vector of time-specific common shocks, and $\lambda _{j}$ are village-specific factor loadings that capture specific responses to the common shocks. The main advantages of this model is that no specific form of the unobserved heterogeneity is imposed, and the model still performs in the absence of common factors. In order to assess the impact of droughts on international migration, we use the following model specification:

(3)\begin{equation} IMR_{j,t}=\beta _{0}+\beta _{1}\sum_{i=1}^{5}drought_{j,t-i}+\delta _{j}+\delta _{t}+\epsilon _{j,t}.\end{equation}

$IMR_{j,t}$ is (standardized) international migration rate at the locality level where j and t refer to locality and year, respectively; $\sum _{i=5}^{5}drought_{j,t-i}$ is the number of dry years (or dry agricultural seasons) in the last five years; $\delta _{j}$ and $\delta _{t}$ are locality and year fixed effects respectively, and $\epsilon _{j,t}$ is an error term.

4.2 Benchmark results

Regression results are displayed in tables 1, 2, A3 and 3. Table 1 presents the main estimation results of equation (1) for men and women aged 20–69 using alternative drought measures. In all regressions, the results show that the number of droughts has an impact on standardized net migration rates, with significant differences between rural and urban localities. Focusing on the first drought measure, which considers the number of dry episodes during the agricultural season (from June to October) over each intercensal period, the results indicate that one additional dry agricultural season leads to a 0.013 standard deviation (SD) decrease in net migration rate in rural localities for men aged 20–69. The results for women are roughly similar, with an estimated 0.011 SD decrease in net migration rate for this sub-sample. The effects of drought episodes are much less pronounced in urban localities for both men and women, since the sum of the two coefficients is not significantly different from zero. These results are roughly the same when one uses alternative drought measures. Results further indicate that the occurrence of drought episodes during at least two consecutive years does not have any additional effect on net migration rates, as suggested by the non-significance of the dummy variable Consecutive shocks.

Table 2. Drought effects on standardized in-, out- and net migration rates

Sample: Census from 1987, 1998 and 2009. Notes: Standard errors in parentheses corrected for serial correlation over one period and for spatial correlation up to a distance cutoff at 500 km. Std. Dev. corresponds to the standard deviation of net migration rates.

Table 3. Drought effects on standardized international migration rates

Sample: Census from 2009. Notes: Standard errors are clustered at the district of origin and are reported in parentheses. Std. Dev. corresponds to the standard deviation of net migration rates.

Table 2 presents additional results using in- and out-migration rates in addition to net migration rates. The advantage of these alternative dependent variables is that they shed light on the underlying mechanism behind the negative impact of droughts on net migration rates. The results show that the reduction in net migration is driven by droughts encouraging people to leave their (rural) locality, and not by droughts making a (rural) locality less attractive as a migration destination.Footnote ¹⁴ Overall, this first set of results suggests that when a given area is hit by dry episodes, this translates into a change in migration patterns in the localities situated in this area: rural localities experience an increase in emigration flows, so that net migration rates decrease, while no such impact is found in urban localities.

The effect of droughts on net migration rate in rural localities is still robust after the introduction of region-by-period fixed effects (column (2) in table A2, online appendix), but becomes insignificant after the introduction of district-by-period fixed effects (column (3) in table A2). This is not surprising since these interaction terms capture most of the remaining variation. To account for unobserved heterogeneity across villages, we also apply the more flexible Interactive Fixed Effect model for a single factor, and we find that the estimates (column (4) in table A2) are similar to the benchmark results (column (1) in table A2). We deduce from this comparison that the bias induced by unobserved common factors is negligible.

We next assess the extent to which the effects of droughts vary across different demographic groups. Table A3 presents the results of estimating equation (1) for men and women for different age-cohorts. The same patterns can be observed in rural localities: overall, dry episodes significantly increase out-migration rates which translates into a decrease in net migration rates for both men and women. The estimated change in net migration rate following one additional dry agricultural season is particularly strong for younger men aged 20–29.Footnote ¹⁵ We also find that the older the age-cohorts, the smaller the size of the effect. In the case of women, the SD decrease in net migration rate is the strongest for the cohort aged 30–39 (it is equal to 0.012) and ranges between 0.005 and 0.011 for the other cohorts. Unlike men for whom the impact of weather shocks on migration is found to decrease with age, no clear pattern emerges for women.

In urban localities, the results are less clear-cut, making their interpretation uneasy. In the male sub-sample, droughts are indeed found to decrease out-migration which translates into an increase in net migration rates for the older age-cohorts only. The same impact is observed in the female sub-sample whatever the age-cohort (except the youngest one). Table A4 in the online appendix presents the results obtained on the same sub-samples, after including region-by-period fixed effects. As already mentioned, introducing these interaction terms means that the identification of climate effects rests on very slim margins. The number of droughts is thus only significant for the sample of younger men.

Lastly we assess the impact of droughts on (standardized) international migration rates. Given the small occurrence of international moves at the local level in a given year, we are not able to disaggregate international migration rates by age. However, we disaggregate them by main region of destination, in order to take distance as a proxy for migration costs into account.

We consider four groups of countries that are mutually exclusive: (1) neighboring countries, that is countries which share a border with Mali; (2) African countries which do not share a border with Mali; (3) OECD countries excluding France; and (4) France.Footnote ¹⁶ Results on total migration rates and migration rates disaggregated by sex are shown in tables 3 and A5 (online appendix) respectively. Overall, the number of droughts in the last five years is found to increase international migration rates, whether one considers destination countries all together or specific ones, except OECD countries. In column (1) of table 3 which focuses on total outmigration flows, one additional dry agricultural season leads to a 0.045 SD increase in international migration rate. This increase is much higher when one concentrates on migration outflows to neighboring countries ($+$0.090 standard deviation, column (2)) but lower when the focus is on outflows to non-neighboring African countries ($+$0.023 SD, column (3)) and France ($+$0.019 SD).

With regards OECD countries (column (4)), drought frequency is not always significant, and when it is, it has a negative sign, which suggests that one additional dry agricultural season actually reduces migration outflows to these countries, with an estimated SD decrease in migration rate of 0.04. This could be the sign that when hit by a shock, households lose the resources needed to fund long-distance moves. Since strong network effects are at play in migration to France, financial constraints may be less of an issue in this specific case. The coefficients associated with the number of intense dry agricultural seasons are even bigger in size: one additional intense dry agricultural season results in a 0.06 SD increase in international migration rates. Migration outflows towards neighboring countries in particular are found to be strongly responsive, as emigration rates towards this set of destinations more than double when a dry episode occurs. The same comments apply when the sample is disaggregated by sex (table A5). Female international migration rates are about ten times lower than male rates, but they also increase in times of drought, especially toward neighboring countries. All in all, this set of results suggests that rainfall conditions influence both internal and international migration. In times of hardship resulting from poor climatic conditions, people have a higher average propensity to migrate, particularly so towards short-distant, neighborliness countries. There might nevertheless be between-group or between-region heterogeneity in climate effects, which is the focus of the next section.

4.3 Testing for differentiated climate effects

We push forward the previous analyses in order to test for the existence of between-group and/or between-region heterogeneity in climate effects. To this end, we use alternative model specifications that include interaction terms between our drought variable and factors expected to potentially mediate climate effects on migration rates. By so doing, we aim at providing insights into the mechanisms linking climate and migration.

We first assess to what extent the agro-ecological context matters in the drought-migration relationship. Since differences in the agro-ecological context create marked differences in the forms and intensity of agriculture, we expect variation in drought effects according to whether individuals’ beginning-of-period residence was in localities situated in the Desert, the Sahelian or the Sudanese zone. Our prior is that more favorable agro-ecological conditions are associated with a greater availability of effective in situ or on-farm adaptation strategies that may prevent households from using migration as a mechanism for coping with drought. In other terms, because the set of options available to households residing in these areas is likely to be larger, we expect climate effects on migration to be lower.

Regression results are displayed in table A6 (online appendix). Given the mechanism we have in mind, we have excluded urban localities from our sample. Results show that the number of droughts has a significantly different impact on (standardized) net migration rate depending on the agro-ecological zone. The impact is the strongest in arid areas and the smallest in semi-arid areas. The size of climate effects on migration in the arid zone suggests that in this area, certain thresholds or “tipping points” may be reached, so that people living there have little choice left but to move when SPEI values deviate from their “normal” values. Similar results are obtained with international migration rates (table A7 in the online appendix). Columns (1) to (5) show indeed that the estimated coefficients of the drought variable are larger for arid areas than for semi-arid and semi-humid ones, for migration towards neighboring and OECD countries.

In order to get additional insights on the mechanisms linking climate and migration, we test whether crop diversification plays a role. To this end, we use an alternative model specification where the number of droughts is interacted with a crop diversification index ranked in quintiles. Crop diversification is measured here by the Gini-Simpson index. It is defined as $D_{i}=1-\sum _{i=1}^{j}s_{i}^{2}$ where s is the share of farmland allocated to a particular crop category and i indicates one of the j possible crops grown by farmers. $D_{i}$ ranges between 0 and 1. The higher the index, the more diversified the land uses. To construct this index, we exploit the EarthStat dataset of croplands on a $10\,{\rm km}\times 10\,{\rm km}$ latitude/longitude gridFootnote ¹⁷ that informs about the share of farmland allocated to the main Malian crops in the year 2000 (yam, cotton, fonio, groundnut, maize, millet, rice, sorghum and tobacco).

Regression results are displayed in table A8 in the online appendix. They show that in localities where crop diversification is the highest, one additional dry agricultural season has a negligible impact on (standardized) net migration rates, while the reverse holds true in localities where it is the lowest.Footnote ¹⁸ Planting different crops could hence be a way to reduce exposure to shocks and make farmers less vulnerable to dry events. However, only detailed data on agricultural incomes could tell whether this interpretation is the correct one, and we unfortunately do not have such data.

Finally, we assess whether individuals’ response to a drought is wealth-dependent. Households’ wealth may impact the drought-migration link in different, contrasted ways. On the one hand, wealthy households may be more able to maintain their level of consumption when hit by a shock than households already close to their subsistence level. They may indeed sell part of their assets and manage to smooth their consumption even if their incomes have dropped sharply. By contrast, poorer households may be forced to move to cope with the effects of drought. On the other hand, individuals at the bottom of the income distribution may be unable to migrate in the event of a shock for lack of resources, and end up being involuntarily immobile. Clearly, understanding how response patterns are distributed is crucial if one aims at designing effective social protection policies against climatic shocks. We thus interact the number of droughts with a wealth index ranked in quintiles and re-run our regressions on both net migration rates and international migration rates.

Our wealth index is a composite indicator computed from households’ dwelling characteristics and asset ownership reported in the census.Footnote ¹⁹ We first performed a principal component analysis to get a wealth index for each household that we averaged at the locality level. Results are provided in tables A9 and A10 (online appendix). Climate effects are found to strongly vary by locality wealth. They are the strongest for poorer localities, and progressively diminish for localities of the top quintiles. Net immigration rates in localities in the fourth and fifth wealth quintiles are even found to increase with the number of dry years. No such clear pattern emerges with international migration rates (table A10): interacted terms are generally not significant, with a few exceptions: interestingly, international migration towards non-neighboring African countries is found to increase with drought frequency only in the richest localities, which may indicate that poverty is a constraint on long-distance migration within the African continent. However, the reverse holds true for migration towards OECD countries, which is found to decline with drought frequency in the richest localities. So further investigation is required to understand the mechanisms at play.

5.1 SPEI and population projections

For our forecast exercise, we use corrected cell-level projections of daily accumulated precipitation and daily mean, minimum and maximum near-surface air temperature from the IPSL-CM5A-LR Atmosphere Ocean General Circulation Model, used in the CMIP5 exercises for the IPCC projection (see Famien et al., Reference Famien, Janicot, Ochou, Vrac, Defrance, Sultan and Noel2018 for more details). The method for calculating evapotranspiration is based on the Hargreaves equation and uses mean, minimum and maximum daily air temperature as well as extraterrestrial solar radiation. We consider two alternative climate scenarios: the RCP 2.6 (also known as the “friendly-climate scenario”) and the RCP 8.5 (the “pessimistic climate scenario”). Average projected drought frequencies over 2018 through 2077 are reported in table A11 (online appendix). Based on predicted SPEI values, it is expected that the number of droughts will significantly increase in both scenarios.

5.2 Projected migration outflows

Regressing unstandardized net migration rates on our drought index shows that one additional drought reduces net migration rate in rural localities by 3.5 and 3.2 percentage points for men and women, respectively. In order to see what these estimates imply for migrant outflows, we use the following formula based on equation (1):

(4)\begin{equation} \frac{\beta_2 }{\overline{NMR_{j,a,[t-11,t]}}}* \frac{\sum_{j=1}^{n,rural}NM_{j,a,1998}*droughts_{j,[t-11,t]}}{11} \end{equation}

where the first term corresponds to the change in percentage of the average net migration rate, which equals $-25.9$ and $-21.7$ per cent for men and women respectively. In order to get an estimate of the volume of additional (net) migration outflows due to the number of dry years over the 1998–2009 period, we first multiply the number of droughts recorded in each locality over the 1998–2009 period by our estimate of the marginal effect of drought on the (net) migrant population measured at the locality level in 1998. As shown by column (7) of table A12 (online appendix), the number of droughts ranged from 0–9 depending on the locality, with a mean of 2.82 over the 1998–2009 period. By summing up these numbers, we then obtain an estimate of the number of additional migrants due to drought episodes for all Malian rural localities over the period 1998–2009. By dividing this number by 11, we finally get the number of additional “drought-induced” migrants in one year.

Based on these computations, we find that the drought episodes that hit Mali between 1998–2009 resulted in an additional net outflow of 7138 male and 6285 female rural migrants per year (figure A4 in the online appendix). We then replicate the exercise using the predicted number of droughts under the “friendly climate scenario” and the “pessimistic climate scenario” (see table A11) over successive 20-year-long time spans. The results are provided in figure A4. In both scenarios, the annual net outflow of “drought-induced” migrants is found to increase as a result of the predicted increase in the number of drought episodes. For the 2058–2078 period, it ranges from 21,409 and 38501 when we consider men and women altogether.

To go one step further, we use the population projections of the United Nations to account for the fact that the Malian population will grow in the next decades (table A13, online appendix).Footnote ²⁰ By so doing, predicted net outflows of “drought-induced” migrants are found to significantly increase: we get an estimated number of 135291 additional (net) migrants in the most pessimistic scenario for the 2058–2077 period. Projected numbers are hence strongly dependent upon the chosen scenario and can be quite large.

In order to get estimates of the number of additional international migrants due to past drought episodes and expected in the next coming decades, we adopt a similar approach. We take the estimated marginal effect of drought from the international migration specification – equation (3) – and apply the following formula:

\[ \frac{\beta _{1}}{\overline{IMR_{j,t}}}\frac{\sum_{j=1}^{n} \;droughts_{j,[t-5,t]}\ast IM_{j,2004}}{5}. \]

Results are provided in table A14 (online appendix). Focusing on column (1), we find that the drought episodes that hit Mali during the 2000s resulted in about 2300 additional international migrants per year over the 2004–2009 period. This figure increases up to 24603 for the 2058–2078 period, when we consider the most pessimistic climate scenario and take population growth into account. This suggests that drought episodes mostly translate into an increase in internal migration flows. In any case, the estimated increase in the number of migrants as a result of potentially dryer decades is significant but not massive.