AI Article Synopsis
- This study examines a stochastic spatial Lotka-Volterra model to analyze predator-prey interactions influenced by periodically changing carrying capacities, which reflect finite food resources for prey.
- The model reveals a continuous phase transition from active to absorbing states, driven by spatiotemporal patterns such as pursuit and evasion waves, with Monte Carlo simulations conducted on a two-dimensional lattice to assess seasonal variations' effects on species coexistence.
- Results show that periodic carrying capacity fluctuations enhance predator-prey coexistence compared to stable environments, though mean-field predictions of period-doubling scenarios are tempered by stochastic noise, highlighting a delay in system responses to environmental changes and persistent spatial correlations.
Article Abstract
We study the stochastic spatial Lotka-Volterra model for predator-prey interaction subject to a periodically varying carrying capacity. The Lotka-Volterra model with on-site lattice occupation restrictions (i.e., finite local carrying capacity) that represent finite food resources for the prey population exhibits a continuous active-to-absorbing phase transition. The active phase is sustained by the existence of spatiotemporal patterns in the form of pursuit and evasion waves. Monte Carlo simulations on a two-dimensional lattice are utilized to investigate the effect of seasonal variations of the environment on species coexistence. The results of our simulations are also compared to a mean-field analysis in order to specifically delineate the impact of stochastic fluctuations and spatial correlations. We find that the parameter region of predator and prey coexistence is enlarged relative to the stationary situation when the carrying capacity varies periodically. The (quasi-)stationary regime of our periodically varying Lotka-Volterra predator-prey system shows qualitative agreement between the stochastic model and the mean-field approximation. However, under periodic carrying capacity-switching environments, the mean-field rate equations predict period-doubling scenarios that are washed out by internal reaction noise in the stochastic lattice model. Utilizing visual representations of the lattice simulations and dynamical correlation functions, we study how the pursuit and evasion waves are affected by ensuing resonance effects. Correlation function measurements indicate a time delay in the response of the system to sudden changes in the environment. Resonance features are observed in our simulations that cause prolonged persistent spatial correlations. Different effective static environments are explored in the extreme limits of fast and slow periodic switching. The analysis of the mean-field equations in the fast-switching regime enables a semiquantitative description of the (quasi-)stationary state.
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| http://dx.doi.org/10.1103/PhysRevE.107.064144 | DOI Listing |
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