Unravelling the Paradoxical Seasonal Food Scarcity in a Peasant Microregion of Mexico
Abstract
:1. Introduction
- A.
- Greater production of maize and beans (which are the bases of the peasant diet) reduces the duration of scarcity and the intensity of coping strategies.
- B.
- Households with more-precarious land tenancy face longer periods of scarcity, and adopt the most intense coping strategies.
- C.
- International migration—although not national or regional migration—significantly reduces the duration of food scarcity and the intensity of coping strategies.
- D.
- Means of production are positively correlated to government support, which determines fewer months of food scarcity, as well as less-intense coping strategies.
- E.
- Significant differences exist in the duration of food scarcity and intensity of coping strategies between the communities that focus on agroforestry versus those that focus on agriculture.
2. Methods
2.1. Study Area and Research Sample
2.2. Ethnographic Fieldwork
2.3. Statistical Analyses
2.4. Social Network Analysis and Visualizations
3. Results
3.1. Temporality and Acuity in Seasonal Food Scarcity and Coping Strategies
3.2. Land Tenancy and Socioeconomic Determinants of Seasonal Food Scarcity and Coping Strategies
3.3. Peasant Agrifood Supply Networks during Scarce and Abundant Seasons
4. Discussion
4.1. Scarcity and Coping-Strategies in the CART, as Compared to Other Peasant Contexts in Central America
4.2. Breaking down Seasonal Food Scarcity in an Attempt to Counteract It in a Targeted Manner
4.3. Seasonal Vulnerability and Robustness in Peasant Food-Supply Networks
5. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Acknowledgments
Conflicts of Interest
Appendix A. Characterization of Food Coping during the Scarce Season
Magnitude Code | Coping Strategy | Description |
---|---|---|
S1 | Reduction in food diversity or consumption | The diversity of more than 50 food products frequently consumed by peasant households is reduced to fewer than 10 products, depending, mainly, on maize and beans. The amount of food consumed regularly during the bounty season can be reduced by almost half during the scarce season. |
S2 | Gathering wild foods | In total, 35 species including greens, fungi, insects, amphibians, small fish, and crustaceans are collected for food from agriculture plots, home gardens, bush, and riverbeds. Some households, practically, base their diets on these products during the scarce season. |
S3 | Sale of backyard animals | Mainly chickens, but turkeys, pigs, and, even, cattle are considered rural savings, so they are sold locally to earn income during the scarce season. |
Pursue agricultural wage labour | It is very common that, to improve their income during the scarce season, which coincides with the agricultural renewal cycle when more paid work is needed, the most disadvantaged households increase the rural daily wages they provide to other productive units. | |
S4 | Temporary migration | Internationally, to the United States through migration networks; nationally, to the north of the country to work as agricultural labourers or to tourist areas to work in construction; and regionally, to nearby cities to work as salaried employees. |
High interest rate loans | Local loan sharks often charge high interest rates on rural loans, in addition to making loans conditional upon mortgaging the means of production, such as land or livestock, on account of repayment. | |
S5 | Parental buffering | Parents stop consuming food for a few days during the lean season, so that their children can continue to eat. |
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Variable | Description | Type | Coding or Mean (% or Range) |
---|---|---|---|
Type of ejido membership | 1. Ejidatario (landholders with voice and vote), 2. Poblador (settlers with voice but no vote), or 3. Avecindado (neighbours with neither voice nor vote) | Categorical | 1 (45%), 2 (21%), 3 (34%) |
Stage of household development cycle | 1. Expansion (newly constituted), 2. dispersal (with children already leaving), or 3. replacement (old) | Categorical | 1 (46%), 2 (26%), 3 (28%) |
Household members | Total number of members in the household | Continuous | 4.4 (2–11) |
Agricultural labour force | Household members whose principal occupation is agriculture | Continuous | 1.5 (0–4) |
Economic activities | Number of agricultural and non-agricultural practiced by the household | Continuous | 2.8 (1–6) |
Type of migration | 1. No migration, 2. regional, 3. national, or 4. international | Categorical | 1 (68%), 2 (7%), 3 (8%), 4 (17%) |
Total labour-days worked | Days worked by all household members | Continuous | 46.2 (0–300) |
Total labour-days paid | Days paid for all economic activities | Continuous | 121.2 (0–1910) |
Total agricultural hectares | Hectares used for agriculture | Continuous | 18.1 (0.5–139) |
Maize production | Tons of total maize yield (for self-supply, animal feed or sale) | Continuous | 4654.6 (0–30,000) |
Bean production | Tons of total bean yield (for self-supply or sale) | Continuous | 285.9 (0–4000) |
Months of food scarcity | Number of months the household reported shortages | Continuous | 2.9 (0–12) |
Eating wild foods | 1. Whether or 2. not the household consumed wild foods | Categorical | 1 (57%), 2 (43%) |
Government assistance | Amount of government assistance the household received | Continuous | 16,045 (0–62,000) |
Income | Total income of the household | Continuous | 56,806 (0–300,000) |
Livestock | Total head of cattle | Continuous | 6.8 (0–80) |
Location in the watershed | 1. Upper (agroforestry in the headwaters) or 2. lower (agropecuary in the central valleys) | Categorical | 1 (50%), 2 (50%) |
Cluster identity | 1 and 2 (social reproduction in accumulation), 3 and 4 (social reproduction squeeze) | Categorical | 1 (4%), 2 (32%), 3 (43%), 4 (21%) |
Metric | Level | Description | Interpretation |
---|---|---|---|
Nodes | Global | Total number of basic data structure units | Shows changes in size, cohesion and dissociation of the supply by food type between abundant and scarce seasons |
Edges | Global | Total number of links | |
Density | Global | Total number of existing links, divided by total links possible in the network | |
Average degree | Global | Measurement of the number of edges versus the number of nodes | |
Average in degree centrality | Global | Average connectivity per node | |
Global efficiency | Global | Efficiency of a node pair in a graph is the multiplicative inverse of the shortest path distance between nodes. Average global efficiency of a graph is the average efficiency of all node pairs | Enables observation of changes in the food-supply flow between abundant and scarce seasons |
Average page rank | Global | A centrality metric that results from an algorithm, which measures the network ranking on a scale of 1–10, based on the weight, the quantity, and the quality of links | Enables the observation of changes in the robustness of the supply by food type, between seasons |
Average node connectivity | Global | The minimum number of nodes that must be removed to break all paths from source to target | Enables observation of supply vulnerability by food type between seasons |
Connected components | Global | Number of subgraphs in which any two vertices are connected to each other by paths and which are connected to no additional vertices in the supergraph | Enables observation of changes in food supply groupings between seasons |
Average out-degree centrality | Global | The out-degree centrality for a node is the fraction of nodes that its outgoing edges are connected to | Captures the centrality of a provider in the supply for all households |
Local efficiency | Local | The local efficiency of a node in the graph is the average global efficiency of the subgraph, induced by the neighbours of the node. The average local efficiency is the average of the local efficiencies of each node | Allows observation of changes in the food supply flows at node level, between abundant and scarce seasons |
Average node strength | Local | The sum of link weights connected to all nodes | Reports changes in the food flows that the nodes hold within the network |
Self-loops | Local | Nodes connected to themselves | Shows directly the importance of self-sufficiency, for each food and season |
Variables | Seasonal Food-Scarcity Months | Livestock | Government Assistance |
---|---|---|---|
Total maize production (kg) | −0.38 *** | ||
Maize production for self-sufficiency | −0.12 ns | ||
Proportion of maize production for self-sufficiency | 0.56 *** | ||
Maize production for sale | −0.01 ns | ||
Proportion of maize production for sale | −0.01 ns | ||
Maize production for livestock | −0.59 *** | ||
Proportion of maize production for livestock | −0.68 *** | ||
Total bean production | −0.10 ns | ||
Bean production for self-sufficiency | 0.03 ns | ||
Proportion of bean production for self-sufficiency | 0.38 *** | ||
Bean production for sale | −0.20 * | ||
Proportion of bean production for sale | −0.31 *** | ||
Total agricultural hectares | −0.64 *** | 0.84 *** | 0.53 *** |
Livestock | −0.65 *** | - | 0.51 *** |
Government assistance | −0.39 *** | 0.51 *** | - |
Economic activities | −0.10 ns | ||
Number of household members | 0.15 ns | ||
Agricultural labour force | 0.20 * |
Coping Strategies | |||||
---|---|---|---|---|---|
Type of ejido membership | 1 | 2 | 3 | 4 | 5 |
Avecindado | 4 (−3.70) | 14 (−0.06) | 8 (3.04) | 6 (0.93) | 5 (2.15) |
Poblador | 7 (−0.09) | 12 (1.82) | 0 (−1.81) | 2 (−0.53) | 1 (0.47) |
Ejidatario | 18 (3.94) | 8 (−1.60) | 1 (−1.51) | 3 (−0.48) | 0 (−1.81) |
Type of migration | 1 | 2 | 3 | 4 | 5 |
International | 2 (0.76) | 0 (−1.61) | 0 (−0.69) | 2 (2.34) | 0 (−0.55) |
National | 3 (−0.19) | 0 (2.64) | 0 (−1.13) | 7 (5.88) | 0 (−0.90) |
No migration | 20 (−0.96) | 34 (4.25) | 8 (1.00) | 0 (−6.18) | 5 (0.47) |
Regional | 4(1.10) | 0 (−2.33) | 1 (0.23) | 2 (1.14) | 1 (0.68) |
Location in the watershed | 1 | 2 | 3 | 4 | 5 |
Upper | 24 (3.51) | 16 (−1.36) | 2 (−2.17) | 5 (−0.77) | 3 (−0.32) |
Lower | 5 (−3.51) | 18 (1.36) | 7 (2.17) | 6 (0.77) | 3 (0.32) |
Food Type | Local Name | Scientific Name | Gathering Unit |
---|---|---|---|
Herbs and vegetables | Hierba mora | Solanum nigrum | Polycrop |
Chipilín | Crotalaria longirostrata | Polycrop | |
Orejita | Porophylum ruderale | Polycrop | |
Bledo | Amaranthus blitoides | Polycrop | |
Canutillo | Hamelia patens | Polycrop | |
Hierba santa | Piper auritum | Bush | |
Berro | Nasturtium officinale | Polycrop | |
Chaya | Cnidoscolus aconitifolius | Bush | |
Verdolaga | Portulaca oleracea | Bush | |
Nabito | Brassica napus | Polycrop | |
Ejote de monte | Phaseolus vulgaris | Bush | |
Cilantro de monte | Peperomia peltilimba | Bush | |
Inflorescences, fruits, meristems, and roots | Flor y puntas de Calabaza | Cucurbita lundelliana | Polycrop |
Puntas de chayote | Sechium chinantlense | Bush | |
Pacaya | Chamaedorea tepejilote | Bush | |
Anona | Annona reticulata | Bush | |
Cuscuta | Amphipterygium adstringens | Bush | |
Tomatillo de monte | Lycopersico esculentum | Bush | |
Tubercles | Madre maíz | Mirabilis sp. | Bush |
Stalks | Nopal espinero | Opuntia | Bush |
Nopal masetero | Opuntia | Home garden | |
Mushrooms | Hongo blanco | Tremelloscypha gelatinosa | Bush |
Hongo orejita de cochi | Hypomyces lactifluorum | Bush | |
Insects | Hormiga chicatana | Atta mexicana | Bush |
Gusano zats | Arsenura armida | Bush | |
Chapulín | Sphenarium purpurascens | Polycrop | |
Reptiles | Iguana verde | Iguana iguana | Bush |
Iguana negra | Ctenosaura pectinata | Bush | |
Turipache | Corytophanes percarinatus | Bush | |
Fish | Macabí | Albula vulpes | River |
Mojarra de río | Diplodus vulgaris | River | |
Charal de río | Chirostoma sp. | River | |
Carpa de río | Cyprinus carpio | River | |
Crustaceans | Cangrejos de río | Astacoidea and Parastacoidea | River |
Snails | Caracoles chuti | Pachychilidae | River |
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Rivera-Núñez, T.; García-Barrios, L.; Benítez, M.; Rosell, J.A.; García-Herrera, R.; Estrada-Lugo, E. Unravelling the Paradoxical Seasonal Food Scarcity in a Peasant Microregion of Mexico. Sustainability 2022, 14, 6751. https://doi.org/10.3390/su14116751
Rivera-Núñez T, García-Barrios L, Benítez M, Rosell JA, García-Herrera R, Estrada-Lugo E. Unravelling the Paradoxical Seasonal Food Scarcity in a Peasant Microregion of Mexico. Sustainability. 2022; 14(11):6751. https://doi.org/10.3390/su14116751
Chicago/Turabian StyleRivera-Núñez, Tlacaelel, Luis García-Barrios, Mariana Benítez, Julieta A. Rosell, Rodrigo García-Herrera, and Erin Estrada-Lugo. 2022. "Unravelling the Paradoxical Seasonal Food Scarcity in a Peasant Microregion of Mexico" Sustainability 14, no. 11: 6751. https://doi.org/10.3390/su14116751
APA StyleRivera-Núñez, T., García-Barrios, L., Benítez, M., Rosell, J. A., García-Herrera, R., & Estrada-Lugo, E. (2022). Unravelling the Paradoxical Seasonal Food Scarcity in a Peasant Microregion of Mexico. Sustainability, 14(11), 6751. https://doi.org/10.3390/su14116751