A continuous ideal free distribution approach to the dynamics of selfish, cooperative and kleptoparasitic populations

• Published in: Royal Society open science Vol. 3; no. 11; p. 160788
• Main Authors: Reding, Ilona, Kelley, Michael, Rowell, Jonathan T., Rychtář, Jan
• Format: Journal Article
• Language: English
• Published: England The Royal Society Publishing 01.11.2016; The Royal Society
• Subjects: Cooperation; Ideal Free Movement; Interference Competition; Kleptoparasitism; Mathematics; Spatial Structure; Sympatry; interference competition; spatial structure; sympatry; kleptoparasitism; ideal free movement; cooperation
• ISSN: 2054-5703; 2054-5703
• DOI: 10.1098/rsos.160788

Population distributions depend upon the aggregate behavioural responses of individuals to a range of environmental factors. We extend a model of ideally motivated populations to describe the local and regional consequences of interactions between three populations distinguished by their levels of cooperation and exploitation. Inspired by the classic prisoner's dilemma game, stereotypical fitness functions describe a baseline non-cooperative population whose per capita fitness decreases with density, obligate co-operators who initially benefit from the presence of conspecifics, and kleptoparasites who require heterospecifics to extract resources from the environment. We examine these populations in multiple combinations, determine where both local and regional coexistence is permitted, and investigate conditions under which one population will invade another. When they invade co-operators in resource-rich areas, kleptoparasites initiate a dynamic instability that leads to the loss of both populations; however, selfish hosts, who can persist at low densities, are immune to this risk. Furthermore, adaptive movement may delay the onset of instability as dispersal relieves dynamic stress. Selfish and cooperative populations default to mutual exclusion, but asymmetric variations in interference strength may relax this condition and permit limited sympatry within the environment. Distinct sub-communities characterize the overall spatial structure.