Conceptual framework

Following George, Adelaja, and Weatherspoon (Reference George, Adelaja and Weatherspoon2020), we define a household food consumption demand model based on a constrained utility maximization problem to explain how FH conflicts influence rural households’ food insecurity. Consider an agricultural household that derives utility from the consumption of its own-produced food ( ${F_o}$ ) and market-purchased food ( ${F_m}$ ). Let $F$ be the total consumption demand for food, and then, the equilibrium demand for food consumption can be presented as follows:

(1) $$F = {F_o} + {F_m}$$

To facilitate our analysis, we assume that total food consumption demand (including the level of food insecurity) is affected by household income (Y) and production inputs (X). We further assume that FH conflicts ${\rm{\;}}\left( \tau \right)$ have impacts on household income and production inputs, which finally affects household food consumption. Thus, the equilibrium demand for food consumption can be derived as:

(2) $$F = (Y(\tau ),X(\tau ))$$

where $Y$ is household income, $X$ indicates inputs used in the production process, and $\tau $ denotes FH conflicts.

When FH conflicts occur, not all farming households in the community are directly affected. Therefore, we make a case for this by splitting the impact of FH conflicts into two – incidence of FH conflict and severity of FH conflict. Figure 1 depicts the key channels through which the two types of conflicts affect food insecurity.

Figure 1. Conceptual framework capturing the impacts of FH conflicts on food insecurity.

The incidence of FH conflicts can affect food insecurity by directly influencing farm production (arrows 1 and 2) or by directly influencing farm production and then indirectly affecting household income (arrows 1, 3, and 4). The incidence of FH conflicts causes uncertainty and anxiety. Therefore, farmers influenced by the FH conflicts tend to make less efficient production decisions. For example, in agricultural production, farmers affected by conflicts may shift away from high investment activities like perennial cropping to short-term, lower yield seasonal cropping, as depicted by the arrow (1) in Figure 1. This argument is supported by previous studies showing that incidences of terrorist events reduce the availability of hired labor, total outputs, and productivity (Adelaja and George Reference Adelaja and George2019; George, Adelaja, and Weatherspoon Reference George, Adelaja and Weatherspoon2020; Arias, Ibáñez, and Zambrano Reference Arias, Ibáñez and Zambrano2019). Reduced production can directly impact food insecurity in terms of food availability for subsistence farmers (arrow 2). It can also negatively impact sales revenue and household income (arrow 3), increasing food insecurity because of decreased food purchasing power (arrow 4). Brück, d’Errico, and Pietrelli (Reference Brück, d’Errico and Pietrelli2019) also found that violent conflicts reduce households’ adaptive capacity via abridged income stability and diversification, which, in turn, increase food insecurity (arrows 3 and 4).

The severity of FH conflicts can also affect food insecurity either directly (arrow 6) or indirectly (arrows 5, 3, and 4). Violent clashes, which lead to the injury and/or death of household members, loss of crop yield, and destruction of farm property, may directly and immediately affect household food insecurity through a reduction in the immediate availability of food (arrow 6). Farmers severely affected by FH conflicts may also shift their production practices from profitable commercial cultivation to subsistence farming to ensure the food demands of their households, resulting in negative consequences for farm productivity (Arias, Ibáñez, and Zambrano Reference Arias, Ibáñez and Zambrano2019; Adelaja and George Reference Adelaja and George2019) (arrow 5). Similarly, risk-averse farmers may also change from perennial cultivation to less risky and less profitable seasonal cultivation (Arias, Ibáñez, and Zambrano Reference Arias, Ibáñez and Zambrano2019). This will have consequences for their food security through a reduced income trajectory and the subsequent inability to access food through the markets (Deininger Reference Deininger2003; Justino Reference Justino2011) (arrows 3 and 4).

Econometrically, the influence of FH conflicts on food insecurity can be derived from the Kuhn-Tucker condition with respect to τ based on Equation (2). Formally, it can be expressed as follows:

(3) $${{\partial F} \over {\partial \tau }} = \left( {{{\partial F} \over {\partial Y}}.{{\partial Y} \over {\partial \tau }}} \right) + \left({{\partial F} \over {\partial X}}.{{\partial X} \over {\partial \tau }}\right)$$

where τ denotes the conflict measures – incidence or severity of FH conflicts. Equation (3) indicates that FH conflicts affect food consumption through their impacts on total household income and production inputs demanded.

As indicated earlier, we are focusing on the availability and accessibility pillars of food security in this study. Measures of food insecurity capturing the accessibility and availability of food will have an inverse relationship with household food consumption demands. For the purpose of analytical settings, we introduce ${\rho _j}$ , a food insecurity (FI) shock, related to F such that $F{I_j} = {\rho _j}F$ , where $F{I_j}$ is the food insecurity measure (i.e., either the incidence or severity of FH conflicts) and ${\rho _j}$ is the coefficient related to the $j$ -th food insecurity measure. Given the inverse relationship between $F$ and $F{I_j}$ , ${\rho _j}$ is assumed to be negative, that is, ${\rho _j}$ < 0. The effects of FH conflict on household food insecurity can then be denoted as:

(4) $${{\partial F{I_j}} \over {\partial \tau }} = {\rho _j}[\left( {{{\partial F} \over {\partial Y}}.{{\partial Y} \over {\partial \tau }}} \right) + \left( {{{\partial F} \over {\partial X}}.{{\partial X} \over {\partial \tau }}} \right)]$$

where ${{\partial F{I_j}}}\over{{\partial \tau }}$ captures the impact of FH conflicts on food insecurity. ${\rm{}}{{\partial F} \over {\partial Y}}.{{\partial Y} \over {\partial \tau }}$ and ${\rm{}}{{\partial F} \over {\partial X}}.{{\partial X} \over {\partial \tau }}$ are expected to be negative because, as discussed earlier, FH conflicts have negative impacts on household income and farm production. The intensity of food insecurity will vary as ${\rho _j}$ varies. Consequently, this will be reflected in the differential impacts of FH conflicts on various food insecurity measures.

Following our conceptual framework above, we define the indirect and direct effects of FH conflicts as the incidence of FH conflicts ( ${\tau _{in}}$ ) and severity of FH conflicts ( ${\tau _{se}}$ ) and make the following two hypotheses:

Empirical strategy

It is challenging to estimate the impacts of FH conflicts on food insecurity using an ordinary least square regression model because of potential endogeneity issues related to FH conflicts. FH conflicts do not occur randomly (Eberle, Rohner, and Thoenig Reference Eberle, Rohner and Thoenig2020). These conflicts usually break out in agrarian communities with specific institutional and environmental characteristics. When it happens, the severity of an FH conflict is not random either, as households with more assets and access to farmlands may be targeted. Following previous studies (Nie, Ma, and Sousa-Poza Reference Nie, Ma and Sousa-Poza2020; Wan et al. Reference Wan, Small, Bekelman and Mitra2015), we employ a 2SPS approach to account for endogeneity issues.

In the first stage, the incidence and severity of FH conflict variables are regressed as functions of a vector of control variables and instrumental variables. Then, the FH conflict variables are predicted. Formally, the first-stage equations are estimated as follows:

(5a) $$Incidenc{e_i} = {\alpha _i}{X_i} + {\beta _i}IV{1_i} + {\varepsilon _i}$$

(5b) $$Severit{y_i} = {\gamma _i}{X_i} + {\delta _i}IV{2_i} + {\eta _i}$$

where $Incidenc{e_i}$ indicates the incidence of FH conflicts; $Severit{y_i}$ indicates the severity of FH conflicts; ${X_i}$ represents a vector of the control variables (e.g., age, gender, education, household size, and farm size); $IV{1_i}$ and $IV{2_i}$ are the two instrumental variables used for the 2SPS model identification; ${\alpha _i}$ , ${\beta _i}$ , ${\gamma _i},$ and ${\delta _i}$ are the parameters to be estimated; ${\varepsilon _i}$ and ${\eta _i}$ are two error terms.

$IV{1_i}$ refers to a variable (IV1) defined as the time taken when travelling from the household to the closest police station, and $IV{2_i}$ refers to a variable (IV2) capturing the distance from the household to the closest police station.Footnote ¹ The majority of rural households live in their ancestral homes and so do not choose where to live. Under this condition, the further away a household is from a police station with security operatives in attendance, the higher the likelihood of an incidence of FH conflicts. Thus, the distance variables can be justified as valid IVs. Following previous studies (Di Falco, Veronesi, and Yesuf Reference Di Falco, Veronesi and Yesuf2011; Amadu, McNamara, and Miller Reference Amadu, McNamara and Miller2020; Manda et al. Reference Manda, Alene, Tufa, Abdoulaye, Wossen, Chikoye and Manyong2019), we employ a falsification test to check the validity and effectiveness of the Ivs in this study. The results (Table A1 in the Appendix) show that distance variables are significantly correlated with the FH conflict variables, but they are not significantly associated with the two food insecurity variables. Thus, we can conclude that both IV1 and IV2 can be used as valid Ivs in the 2SPS models.

In the second stage, the food insecurity variable is regressed as a function, in which the predicted conflict variable is used to replace the original conflict variable. Formally, we estimate the following two equations:

(6a) $$Insecurit{y_i} = {\theta _i}Incidence_i^P + {\zeta _i}{X_i} + {\nu _i}$$

(6b) $$Insecurit{y_i} = {\varphi _i}Severity_i^P + {\phi _i}{X_i} + {\omega _i}$$

where $Insecurit{y_i}$ refers to food insecurity indicators. $Incidence_i^P$ refers to the predicted variable representing the incidence of FH conflict; $Severity_i^P$ refers to the predicted variable representing the severity of FH conflict. As shown in previous studies (Mishra and Moss Reference Mishra and Moss2013; Wooldridge Reference Wooldridge2015), the predicted variables control for endogeneity issues and improve the efficiency of model estimations. ${X_i}$ is defined earlier. ${\theta _i}$ , ${\zeta _i}$ , ${\varphi _{i,}}$ and ${\phi _i}$ are parameters to be estimated. ${\nu _i}$ and ${\omega _i}$ are error terms capturing the unobserved heterogeneities.

Data

The study uses primary farm household data collected between May and June 2019 in Nigeria. The information collected refers to the 2018 planting season. The sample was selected using a multistage sampling approach. First, we purposively selected the North central and Southeast geopolitical zones in Nigeria because they are the most food secure and least food secure zones (Nnaji, Ratna, and Renwick Reference Nnaji, Ratna and Renwick2020). According to the preliminary analysis, the North central zone was found to be the most food secure zone, while the Southeast was food insecure. Other secondary sources also suggest that the North central zone had the most occurrences of FH conflicts, while the Southeast zone had fewer incidences of FH conflicts. The purposive selection of these two regions helps increase the chances of variation in the data collected, making our samples more representative. Second, we purposively selected one state in each zone, then five local government areas (LGAs) in each state, based on the previous occurrences of FH conflicts. Third, two towns from each LGA and then two villages from each town were randomly selected. Finally, approximately ten households in each village were randomly selected to answer the interview questionnaire, contributing to a total of 401 households.

We conducted the survey with the assistance of enumerators who usually help the projects of the International Food Policy Research Institute, Abuja office, Nigeria. The enumerators spoke both English and local dialects so they could control the survey quality. Before the formal survey, we improved the questionnaire based on the feedback collected from the pre-test samples. We also trained the enumerators to make sure they clearly understood the survey objectives and questions covered in the questionnaire, guaranteeing accuracy and efficiency of data collection. The information derived from the survey related to the 2018 planting season and focused on information, such as household, household head, and farm-level characteristics, asset ownership, and land tenure rights. Questionnaires were administered to household heads on behalf of the household. The households in our sample mainly cultivate crops such as cassava, yam, soybean, and maize and raise livestock such as poultry, sheep, and goats for livelihoods.

Variable measurements

Descriptive statistics

Table 1 provides the summary statistics of the selected variables in the study. The control variables are selected by drawing upon the existing literature on conflicts and food security (Brück and d’Errico Reference Brück and d’Errico2019; Martin-Shields and Stojetz Reference Martin-Shields and Stojetz2019; D’Souza and Jolliffe Reference D’Souza and Jolliffe2013; George, Adelaja, and Weatherspoon Reference George, Adelaja and Weatherspoon2020; Arias, Ibáñez, and Zambrano Reference Arias, Ibáñez and Zambrano2019; Brück, d’Errico, and Pietrelli Reference Brück, d’Errico and Pietrelli2019). The food insecurity measures, HFIAS and CSI, are continuous variables. In particular, the value of HFIAS ranges between 0 and 27 and has a mean of 11.27. The value of CSI ranges from 0 to 93 and has a mean of 22.12. The incidence of the FH conflict variable is continuous, with a mean of about 4 (out of 28). This implies that, on average, FH conflicts occurred about four times in the communities surveyed in 2018. The severity of the FH conflict variable is a proportion that has a mean of 0.59 with a standard deviation of 0.39. The closer the value is to one for a household, the more severe its food insecurity.

Table 1. Variable definitions and descriptive statistics

Note: a ₦ is Nigerian currency (US$1 = ₦ 380), S.D. refers to standard deviation.

In our sample, the average rural household head is aged about 49, which is very close to the age reported in previous studies (Etowa, Nweze, and Arene Reference Etowa, Nweze and Arene2014; George, Adelaja, and Awokuse Reference George, Adelaja and Awokuse2021; Delvaux and Paloma Reference Delvaux and Paloma2018). The average education is just more than eight years of formal education (Table 1). Twenty-four percent of our sampled household heads are female. On average, the households have around nine members and cultivate around seven different crops on about 1.59 hectares of land. In comparison, Ecker and Hatzenbuehler (Reference Ecker and Hatzenbuehler2021) reported an average farm size of about 2.35 hectares when estimating the Nigerian General Household Survey (GHS) data, and George, Adelaja, and Awokuse (Reference George, Adelaja and Awokuse2021) reported an average farm size of 3.77 hectares when estimating the same data set. The difference is not impossible, given the fact that the GHS captures households in all geopolitical zones in Nigeria, especially zones with higher landmass than the zones captured in this study (North central and Southeast). A quarter of household heads perceive that the quality of the road from their residing village to farmland is good. Only 14% of households have formal land titles. The average household income is 44,800 naira/capita/year (US$1 = 380 naira), which is higher than the income reported by Etowa, Nweze, and Arene (Reference Etowa, Nweze and Arene2014), which is 29,504.06 naira/capita/year. The difference could be attributed to inflation over time.