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Abstract
We study the organization of mixed-mode oscillations (MMOs) in the
Olsen model for the peroxidase-oxidase reaction, which is a
four-dimensional system with multiple time scales. A numerical
continuation study shows that the MMOs appear as families in a
complicated bifurcation structure that involves many regions of
multistability. We show that the small-amplitude oscillations of the
MMOs arise from the slow passage through a (delayed) Hopf bifurcation
of a three-dimensional fast subsystem, while large-amplitude
excursions are associated with a global reinjection mechanism. To
characterize these two key components of MMO dynamics geometrically we
consider attracting and repelling slow manifolds in phase space. More
specifically, these objects are surfaces that are defined and computed
as one-parameter families of stable and unstable manifolds of saddle
equilibria of the fast subsystem. The attracting and repelling slow
manifolds interact near the Hopf bifurcation, but also explain the
geometry of the global reinjection mechanism. Their intersection gives
rise to canard-like orbits that organize the spiralling nature of the
MMOs.
Mathematics Subject Classification: Primary: 58F15, 58F17; Secondary: 53C35.
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