English

Colonization times in Moran process on graphs

Populations and Evolution 2024-10-15 v1 Probability

Abstract

Moran Birth-death process is a standard stochastic process that is used to model natural selection in spatially structured populations. A newly occurring mutation that invades a population of residents can either fixate on the whole population or it can go extinct due to random drift. The duration of the process depends not only on the total population size nn, but also on the spatial structure of the population. In this work, we consider the Moran process with a single type of individuals who invade and colonize an otherwise empty environment. Mathematically, this corresponds to the setting where the residents have zero reproduction rate, thus they never reproduce. We present two main contributions. First, in contrast to the Moran process in which residents do reproduce, we show that the colonization time is always at most a polynomial function of the population size nn. Namely, we show that colonization always takes at most 12n312n2\frac12n^3-\frac12n^2 expected steps, and for each nn, we exactly identify the unique slowest spatial structure where it takes exactly that many steps. Moreover, we establish a stronger bound of roughly n2.5n^{2.5} steps for spatial structures that contain only two-way connections and an even stronger bound of roughly n2n^2 steps for lattice-like spatial structures. Second, we discuss various complications that one faces when attempting to measure fixation times and colonization times in spatially structured populations, and we propose to measure the real duration of the process, rather than counting the steps of the classic Moran process.

Keywords

Cite

@article{arxiv.2410.09476,
  title  = {Colonization times in Moran process on graphs},
  author = {Lenka Kopfová and Josef Tkadlec},
  journal= {arXiv preprint arXiv:2410.09476},
  year   = {2024}
}

Comments

25 pages, 11 figures

R2 v1 2026-06-28T19:18:56.542Z