2.1 Fragility and climate change in SSA: acute and correlated phenomena

Figure A1 in the online appendix shows that SSA is the most fragile region compared to South America, Europe and North America in 2023 (Fund for Peace, 2022). Several reasons could explain the severity of state fragility in this part of the world. The 1990s witnessed the emergence of state fragility in SSA, driven by economic shocks such as the 1995 recession, characterized by currency devaluations and falling oil prices. Subsequently, the 2008 food riots, exacerbated by the subprime crisis, coupled with recurring post-election crises and the rise of secessionist and jihadist movements, further compounded state fragility in the region (ACLED, 2021). In addition to all these reasons, climate change is identified as one of the factors exacerbating state fragility in SSA (IPCC, 2022).

Figure A2 in the online appendix shows the persistence of climate change in SSA. Average temperatures have risen from 27.1°C in 2000 to over 28°C in 2010 and averaged around 27.7°C in 2020. These findings are consistent with the IPCC (2019), which highlights the heightened vulnerability of the African continent to climate change impacts resulting from global temperature increases. Despite an observed increase in rainfall, the pattern is highly irregular, with significant variations in both timing and intensity (figure A2). This irregularity underscores a key aspect of climate change, i.e., a disruption of the predictable seasonal rainfall patterns.

The potential links between state fragility and climate change are highlighted in the correlation graphs (figure A3 in the online appendix). According to these graphs, the correlation between average temperatures and state fragility is positive. As temperatures rise, SSA states become increasingly fragile. Similarly, there is a negative correlation between overall fragility and average rainfall, such that any increase in average rainfall is associated with a decrease in fragility, and vice versa. Thus, like Mbaye and Signé (Reference Mbaye and Signé2022), our correlation analyses suggest a link between climate change and state fragility in SSA.

2.2 Fragility in SSA: a heterogeneous phenomenon

Figure A1 in the online appendix highlights the heterogeneity of fragility in SSA, as shown by Ongo Nkoa and Song (Reference Ongo Nkoa and Song2021). East Africa appears to be the region most affected by fragility. According to WFP (Reference WFP2023), almost 23 million people in Ethiopia, Kenya and Somalia are food insecure due to local conflicts, the Covid-19 pandemic, rising food prices due to the war in Ukraine and, most importantly, drought and reduced rainfall. Central and West Africa also show a significant fragility level. This is due to the security context and political instability resulting from multiple conflicts, as well as the weak capacity of states to respond to security and climate change issues (AfDB, 2019; Ateba and Ongo, Reference Ateba and Ongo2024). While Southern Africa may exhibit lower fragility compared to other sub-regions, it still faces significant challenges. These include xenophobic conflicts and insurgencies, high levels of inequality and poverty (Baffi and Vivet, Reference Baffi and Vivet2017), and the increasing frequency of extreme weather events, particularly tropical cyclones, in countries like Malawi, Mozambique, and Zimbabwe (AfDB, 2022).

3.1 A theoretical explanation through the multidimensional approach of State fragility

Carment et al. (Reference Carment, Samy, Hales, Miller, St. Jean and Tikuisis2010) and Nay (Reference Nay2013) criticise the one-dimensional approach to State fragility insofar as it refers to isolated concepts such as weak institutional governance, state corruption, economic crises, civil conflict and war, extreme poverty, crime or food insecurity. As the notion of state fragility is inextricably linked to multidimensional issues, Carment et al. (Reference Carment, Samy, Hales, Miller, St. Jean and Tikuisis2010) develop a theoretical framework for state fragility based on a multidimensional approach. This theory is based on the Authority-Legitimacy-Capacity triptych and refers to the conditions that must be met for a State to escape the category of ‘fragile state’. Authority is understood as the coercive force of the state. Legitimacy refers to the recognition of the state by the people, and Capacity refers to the state's ability to regulate shocks. According to Faria (Reference Faria2011), fragility encompasses a number of concepts, such as the lack of authority and legitimacy of the state and its inability to meet its obligations in the event of shocks. In the context of climate change, Hamza and Corendea (Reference Hamza and Corendea2012) point out that fragility arises from the inability of authority to assert its power in regions affected by climate change, and its inability to mobilise and use the resources that would enable the population to access basic food and services in the event of climate change shocks. Huang (Reference Huang2018) states that climate change exerts pressure on the limited resources of vulnerable populations, and reduces the legitimacy of the state due to its inability to provide basic and necessary human services. One of the most serious consequences of climate change is the instability of states to recover from disasters and manage their inherent risks, due to the pressure it places on already weak institutions (Faria, Reference Faria2011). Ultimately, in the event of climate change shocks, the lack of authority and legitimacy of the State and its inability to improve the well-being of the population exacerbate fragility (Stewart and Brown, Reference Stewart and Brown2009).

3.2 Climate change and state fragility: effects and mechanisms in empirical studies

4.1 The model and the data

Our model is inspired by the work of Jaramillo et al. (Reference Jaramillo, Cebotari, Diallo, Gupta, Koshima, Kularatne, Lee, Rehman, Tintchev and Yang2023) who analysed the effect of climate change on fragilities using a two-way fixed effects panel data model. In this study, we analyse the effects of climate change on all indicators of fragility and on the composite index of global fragility. The empirical model is written as follows:

(1)\begin{equation}Fragilit{y_{k,it}} = \beta + \gamma C{C_{it}} + {X_{it}}\lambda + {\psi _i} + {\rho _t} + {\varepsilon _{it}}\end{equation}

with k = overall fragility, economic, social, political, and security; i = 1, 2,…,45, and t = 1995,1996,…, 2020.

For these specifications, the results of the Hausman tests (in online appendix table A1) justify the choice of fixed effects models rather than random effects models. Fixed effects models have the advantage of incorporating the temporal and individual dimensions, thus allowing endogeneity problems to be taken into account (Burke et al., Reference Burke, Hsiang and Miguel2015; Jaramillo et al., Reference Jaramillo, Cebotari, Diallo, Gupta, Koshima, Kularatne, Lee, Rehman, Tintchev and Yang2023). Fixed effects models can reduce omitted variable bias by addressing unobserved heterogeneity across individuals in the panel (Hill et al., Reference Hill, Johnson, Greco, O'Boyle and Walter2021). Thus, ${\Psi _i}$ controls for time-invariant unobserved variables at the country level such as culture and geography, while time-fixed effects, ${\rho _t}$, control for time variant shocks that are common to all countries in the sample.

$Fragilit{y_{k,it}}$ is the column vector of dependent variables, including the composite index of overall fragility and the four disaggregated indices of fragility (see online appendix table A5).Footnote ² Global fragility is captured by the Composite Fragility Index, which is constructed from state fragility indices. The disaggregated indices of overall fragility, including economic, political, security and social dimensions, are derived using PCA on 12 respective indicatorsFootnote ³ ranging from 0 for resilience to 12 for extreme fragility (Fund for Peace, 2022). By applying the arithmetic mean to these four disaggregated indices obtained through PCA, we obtain the composite fragility index, also known as the overall fragility index. Contrary to the work of the OECD (2020), we cannot include environmental fragility among the explained variables. This would lead to reverse causality bias, as climate change is recognised as an indicator of environmental fragility. The Fragility Dimensions Index comes from the Fund for Peace's (2021) State Fragility Index database and has several advantages over other indices such as the Foundation for International Development Studies and Research, Economic Vulnerability Index and the World Bank Fragility Index. First, it provides information on a large panel of SSA countries. Second, the time horizon over which the index is calculated is longer, and third, the number of indicators used to derive the index is larger. $C{C_{it}}$ is the matrix of climate change variables consisting of average temperatures in degrees Celsius (°C), denoted $A{T_{it}}$, and average precipitation in millimetres per years (mm/Year), denoted $A{P_{it}}$, obtained by averaging monthly values of temperature and precipitation. The World Meteorological Organisation (WMO, 2007) defines the average climate level as the mean temperature and precipitation over a 30-year period. Although our analysis relies on a slightly shorter period (1995–2020) due to data limitations, we believe this 26-year average provides a reasonable approximation for capturing climate change trends in our study. Our study utilizes a longer time horizon compared to previous research by Raleigh et al. (Reference Raleigh, Choi and Kniveton2015) and Burke et al. (Reference Burke, Miguel, Satyanath, Dykema and Lobell2009), which employed 14- and 21-year periods, respectively. Monthly data are obtained from the World Bank Group's Climate Change Knowledge Portal (CCKP, 2021), a geo-referenced database primarily sourced from North American institutions such as the National Center for Atmospheric Research and the International Research Institute (Columbia Climate School).

${X_{it}}$ is the vector of control variables all taken from the World Development Indicator database (WDI, 2021). They can be considered as direct determinants of state fragility as well as mechanisms through which climate change influences fragility. $Gdp/ca{p_{it}}$ represents the GDP per capita. It measures the level of economic activity and corresponds to the ratio between the value of GDP and the number of inhabitants of a country. La and Xu (Reference La and Xu2017) argue that increasing GDP per capita, by improving the living conditions of the population, reduces the vulnerability of the state to exogenous shocks. $Popgr{o_{it}}$ is the rate of population growth. The uncontrolled increase of the population growth rate can be a source of state fragility. Williams (Reference Williams2017) shows that the larger the population size and the faster it grows, the easier it is for the population to make demands that can lead to social, economic, and political issues.

$Natre{s_{it}}$ represents natural resources approximated by profits from oil, gas, and mineral products as a percentage of GDP. According to Dupasquier and Osakwe (Reference Dupasquier and Osakwe2006), when the natural resource curse hypothesis is true, natural resource abundance increases the fragility of states.

$Rem{f_{it}}$ represents migrant remittances and the share of income earned abroad. Official remittances are only a small part of the remittances that circulate in the world and can exacerbate conflicts if they are used to purchase arms and munition (Avom et al., Reference Avom, Nkoa and Song2020). However, for Clemens and McKenzie (Reference Clemens and McKenzie2014), remittance funds could reduce economic fragility for recipient countries, as they can address urgent financing needs.

$FD{I_{it}}$ stands for foreign direct investment (currents, net inflows). FDI exhibits multifaceted effects on state fragility. For Santangelo (Reference Santangelo2018), while FDI can reduce unemployment and improve social indicators like health and education, its influence on agriculture can be detrimental, leading to land appropriation and displacement of smallholder farmers. Furthermore, while FDI can enhance economic stability by facilitating technology transfer and driving growth in countries with adequate human capital (Hamid et al., Reference Hamid, Meghna and Saibal2016), it can also increase security fragility by exacerbating macroeconomic instability (Mueller et al., Reference Mueller, Piemontese and Tapsoba2017). Finally, Gossel (Reference Gossel2018) finds that FDI can contribute to a more stable political environment by curbing corruption and fostering democratic institutions. $In{f_{it}}$ represents inflation. According to Akobeng (Reference Akobeng2016) and Avom et al. (Reference Avom, Nkoa and Song2020), inflation is used to explain state fragility following Berazneva and Lee (Reference Berazneva and Lee2013) who showed that rising prices of consumer goods were the cause of food riots and conflicts in most African countries during the 2007–2008 period.

$VOF{P_{it}}$ represents the volatility of agricultural food prices (wheat), derived from monthly FAO data (FAOSTAT, Reference FAOSTAT2021). Hugon and Mayeyenda (Reference Hugon and Mayeyenda2003) use the coefficient of variation to capture price volatility, while in reference to Minot (Reference Minot2014), we used instead standard deviations on monthly food (wheat) consumer price index data. The choice of wheat price volatility is motivated by the fact that wheat, unlike other agricultural crops, is the most vulnerable crop to the effects of climate change (Nelson et al., Reference Nelson, Rosegrant, Koo, Robertson, Sulser, Zhu, Ringler, Msangi, Palazzo, Batka, Magalhaes, Valmonte-Santos, Ewing and Lee2009). For Philipsz (Reference Philipsz2019), the impact of wheat price volatility on purchasing power generates conflict and riots. Based on the above, and taking into account the existing relationships between climate change, fragility and these control variables, considered in the literature as transmission channels, we construct the conceptual model shown in figure A4 in the online appendix.

Overall, there is little variation between variables in the descriptive statistics (see online appendix table A2). The information on the standard deviations suggests that there is a low level of volatility for all the variables analysed (table A2). Correlation analysis (see online appendix table A3) revealed low correlations among explanatory variables, suggesting a lack of multicollinearity. This was further confirmed by the variance inflation factor (VIF) test, which indicated no significant multicollinearity issues (see online appendix table A4).

Table 1. Effects of climate change on state fragility

Notes: Standard errors in parentheses.

4.2 Estimation method and control of endogeneity problems

Our estimation strategy, adapted from Hsiang et al. (Reference Hsiang, Burke and Miguel2013) and Burke et al. (Reference Burke, Hsiang and Miguel2015), employs the two-way fixed effects (TWFE) estimator. This approach mitigates endogeneity bias by effectively controlling for unobserved heterogeneity across individuals within the panel (Wooldridge, Reference Wooldridge2021). A number of arguments support the choice of this estimation strategy (Feeny et al., Reference Feeny, Posso and Regan-Beasley2015). First, the individual dimension allows us to account for the unobserved heterogeneity associated with the probability of a country being fragile or not, and to capture the individual characteristics that are invariant over time, such as the region of the country, the legal origin (colonisation) and specific climatic characteristics. Second, the introduction of the time dimension allows the estimator to mitigate endogeneity due to a suspected correlation between climate change and control variables such as population growth rate, education, natural resources and GDP per capita. Third, the time-specific effect allows us to control for economic or climatic shocks common to fragile countries, such as economic crises and natural disasters. The choice of this estimation technique is validated by the Fisher test which highlights the heterogeneity between individuals in the panel. The robustness of this estimation technique is controlled by the method of lagged explanatory variables (Bellemare et al., Reference Bellemare, Masaki and Pepinsky2017) and the system generalised method of moments (S-GMM) (Blundell and Bond, Reference Blundell and Bond1998).

6.1 Sensitivity tests

To further address the omission of variables bias, the first sensitivity test is conducted by testing the model's sensitivity by adding groups of variables like basics social services access, digital, and historical-cultural variables. The second test focuses on the sub-regional heterogeneity of our panel in order to guide the development of specific analytical approaches.

6.2 Robustness checks