Environment driven oscillation in an off-lattice May–Leonard model

Abstract: Cyclic dominance of competing species is an intensively used working hypothesis to explain biodiversity in certain living systems, where the evolutionary selection principle would dictate a single victor otherwise. Technically the May–Leonard models offer a mathematical framework to describe the mentioned non-transitive interaction of competing species when individual movement is also considered in a spatial system. Emerging rotating spirals composed by the competing species are frequently observed character o… Show more

“…This leads to the emergence of spiral patterns whose characteristic length scales are associated with the parameters [57]. Our numerical implementation follows the May-Leonard framework, widely assumed to investigate spatial games [25,32,58]. We build square lattices with periodic boundary conditions, where each grid point contains at most one individual, which means that the maximum number of organisms is N , the total number of grid points.…”

Spatial patterns and biodiversity in rock-paper-scissors models with regional unevenness

“…This leads to the emergence of spiral patterns whose characteristic length scales are associated with the parameters [57]. Our numerical implementation follows the May-Leonard framework, widely assumed to investigate spatial games [25,32,58]. We build square lattices with periodic boundary conditions, where each grid point contains at most one individual, which means that the maximum number of organisms is N , the total number of grid points.…”

Spatial patterns and biodiversity in rock-paper-scissors models with regional unevenness

The dynamic edge environment under interactive diversity is a double-edged sword

Frequency modes of unstable spiral waves in two-dimensional Rosenzweig–MacArthur ecological networks