The effects of network topology, climate variability and shocks on the evolution and resilience of a food trade network

• Published in: PloS one Vol. 14; no. 3; p. e0213378
• Main Authors: Dolfing, Alexander G, Leuven, Jasper R F W, Dermody, Brian J
• Format: Journal Article
• Language: English
• Published: United States Public Library of Science 26.03.2019; Public Library of Science (PLoS)
• Subjects: Amplitudes; Analysis; Biology and Life Sciences; Carrying capacity; Climate; Climate change; Climate Change - economics; Climate Change - statistics & numerical data; Climate effects; Climate variability; Commerce; Computer and Information Sciences; Computer Simulation; Conservation of Natural Resources - economics; Conservation of Natural Resources - statistics & numerical data; Demonstrations; Earth Sciences; Ecology and Environmental Sciences; Fluctuations; Food; Food industry; Food Industry - economics; Food Industry - statistics & numerical data; Food production; Food supply; Food Supply - economics; Food Supply - statistics & numerical data; Future climates; Global temperature changes; Humans; International economic relations; Models, Economic; Models, Theoretical; Network architectures; Network topologies; Nodes; Population Growth; Rain; Resilience; Resource availability; Social Sciences; Software; Sustainable development; Topology; Variability; Netherlands
• ISSN: 1932-6203; 1932-6203
• DOI: 10.1371/journal.pone.0213378

Future climate change will impose increased variability on food production and food trading networks. However, the effect of climate variability and sudden shocks on resource availability through trade and its subsequent effect on population growth is largely unknown. Here we study the effect of resource variability and network topology on access to resources and population growth, using a model of population growth limited by resource availability in a trading network. Resources are redistributed in the network based on supply and the distance between nodes (i.e. cities or countries). Resources at nodes vary over time with wave parameters that mimic changes in biomass production arising from known climate variability. Random perturbations to resources are applied to study resilience of individual nodes and the system as a whole. The model demonstrates that redistribution of resources increases the maximum population that can be supported (carrying capacity) by the network. Fluctuations in carrying capacity depend on the amplitude and frequency of resource variability: fluctuations become larger for increasing amplitude and decreasing frequency. Our study shows that topology is the key factor determining the carrying capacity of a node. In larger networks the carrying capacity increases and the distribution of resources in the network becomes more equal. The most central nodes achieve a higher carrying capacity than nodes with a lower centrality. Moreover, central nodes are less susceptible to long-term resource variability and shocks. These insights can be used to understand how worldwide equitable access to resources can be maintained under increasing climate variability.