Chaotic turnover of rare and abundant species in a strongly interacting model community

Advances in metagenomic methods have revealed an astonishing number and diversity of microbial lifeforms, most of which are rare relative to the most-abundant, dominant taxa. The ecological and evolutionary mechanisms that generate and sustain broadly observed microbial diversity patterns remain debated. One possibility is that complex interactions between numerous taxa are a main driver of the composition of a microbial community. Lotka-Volterra equations with disordered interactions between species offer a minimal yet rich modelling framework to investigate this hypothesis. We consider communities with strong, mostly competitive interactions, where species-rich coexistence equilibria are typically unstable. When species extinction is prevented by a small rate of immigration, one generically finds a sustained chaotic phase, where all species participate in a continuous turnover of who is rare and who is dominant. The distribution of rare species' abundances -- in a snapshot of the whole community, and for each species individually in time -- follows a distribution with a prominent power-law trend with exponent $\nu>1$. We formulate a focal-species model in terms of a logistic growth equation with coloured noise that reproduces dynamical features of the disordered Lotka-Volterra model. With its use, we discover that $\nu$ is mainly determined by three effective parameters of the dominant community, such as its timescale of turnover. Approximate proportionalities between the effective parameters constrain the variation of $\nu$ across the range of interaction statistics resulting in chaotic turnover. We discuss our findings in the context of marine plankton communities, where chaos, boom-bust dynamics, and a power-law abundance distribution have been observed.