Game theory ideas provide a useful framework for studying evolutionary dynamics in a wellmixed environment. This approach, however, typically enforces a strictly fixed overall population size, deemphasizing natural growth processes. We study a competitive Lotka-Volterra model, with number fluctuations, that accounts for natural population growth and encompasses interaction scenarios typical of evolutionary games. We show that, in an appropriate limit, the model describes standard evolutionary games with both genetic drift and overall population size fluctuations. However, there are also regimes where a varying population size can strongly influence the evolutionary dynamics. We focus on the strong mutualism scenario and demonstrate that standard evolutionary game theory fails to describe our simulation results. We then analytically and numerically determine fixation probabilities as well as mean fixation times using matched asymptotic expansions, taking into account the population size degree of freedom. These results elucidate the interplay between population dynamics and evolutionary dynamics in well-mixed systems.
Standard neutral population genetics theory with a strictly fixed population
size has important limitations. An alternative model that allows independently
fluctuating population sizes and reproduces the standard neutral evolution is
reviewed. We then study a situation such that the competing species are neutral
at the equilibrium population size but population size fluctuations
nevertheless favor fixation of one species over the other. In this case, a
separation of timescales emerges naturally and allows adiabatic elimination of
a fast population size variable to deduce the fluctuations-induced selection
dynamics near the equilibrium population size. The results highlight the
incompleteness of the standard population genetics with a strictly fixed
population size.Comment: Submitted to Journal of Statistical Physics, Special Issue: Dedicated
to the Memory of Leo Kadanoff. arXiv admin note: text overlap with
arXiv:1412.668
Growth in static and controlled environments such as a Petri dish can be used to study the spatial population dynamics of microorganisms. However, natural populations such as marine microbes experience fluid advection and often grow up in heterogeneous environments. We investigate a generalized Fisher-Kolmogorov-Petrovsky-Piscounov (FKPP) equation describing single species population subject to a constant flow field and quenched random spatially inhomogeneous growth rates with a fertile overall growth condition. We analytically and numerically demonstrate that the non-equilibrium steady-state population density develops a flow-driven striation pattern. The striations are highly asymmetric with a longitudinal correlation length that diverges linearly with the flow speed and a transverse correlation length that approaches a finite velocity-independent value. Linear response theory is developed to study the statistics of the steady states. Theoretical predictions show excellent agreement with the numerical steady states of the generalized FKPP equation obtained from Lattice Boltzmann simulations. These findings suggest that, although the growth disorder can be spatially uncorrelated, correlated population structures with striations emerge naturally at sufficiently strong advection.
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