Coupled phase-amplitude dynamics in heterogeneous metacommunities

Coupled phase-amplitude dynamics in heterogeneous metacommunities

•Habitat heterogeneity drives oscillation in predator–prey cycles’ frequency/amplitude.•Coupled frequency-amplitude modulation promotes long-term local & regional stability.•Forced oscillators can show frequency-amplitude modulation via spatial connectivity. Spatial synchrony of population fluct...

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Bibliographic Details
Published in:Journal of theoretical biology Vol. 523; p. 110676
Main Authors: Milne, Russell, Guichard, Frederic
Format: Journal Article
Language:English
Published: England Elsevier Ltd 21-08-2021
Subjects:
Dispersal
Entrainment
Habitat heterogeneity
Synchrony
Variability
Entrainment
Habitat heterogeneity
Dispersal
Variability
Synchrony
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Summary:•Habitat heterogeneity drives oscillation in predator–prey cycles’ frequency/amplitude.•Coupled frequency-amplitude modulation promotes long-term local & regional stability.•Forced oscillators can show frequency-amplitude modulation via spatial connectivity. Spatial synchrony of population fluctuations is an important tool for predicting regional stability. Its application to natural systems is still limited by the complexity of ecological time series displaying great variation in the frequency and amplitude of their fluctuations, which are not fully resolved by current ecological theories of spatial synchrony. In particular, while environmental fluctuations and limited dispersal can each control the dynamics of frequency and amplitude of population fluctuations, ecological theories of spatial synchrony still need to resolve their role on synchrony and stability in heterogeneous metacommunities. Here, we adopt a heterogeneous predator–prey metacommunity model and study the response of dispersal-driven phase locking and frequency modulation to among-patch heterogeneity in carrying capacity. We find that frequency modulation occurs at intermediate values of dispersal and habitat heterogeneity. We also show how frequency modulation can emerge in metacommunities of autonomously oscillating populations as well as through the forcing of local communities at equilibrium. Frequency modulation was further found to produce temporal variation in population amplitudes, promoting local and regional stability through cyclic patterns of local and regional variability. Our results highlight the importance of approaching spatial synchrony as a non-stationary phenomenon, with implications for the assessment and interpretation of spatial synchrony observed in experimental and natural systems.
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ISSN:0022-5193
1095-8541
DOI:10.1016/j.jtbi.2021.110676