Journal
SIAM JOURNAL ON APPLIED DYNAMICAL SYSTEMS
Volume 22, Issue 3, Pages 2312-2356Publisher
SIAM PUBLICATIONS
DOI: 10.1137/22M1541812
Keywords
Allen-Cahn; invasion front; slow parameter ramp; geometric singular perturbation theory; geometric blow-up; bifurcation delay
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This work studies front formation in the Allen-Cahn equation with a parameter heterogeneity that slowly varies in space. The existence, stability, and interface location of positive, monotone fronts are rigorously established for slowly varying ramps. The front location depends on the transition between convective and absolute instability of the base state, causing a delay before the system jumps to a nontrivial state. For stationary ramps, the front is governed by the slow passage through the instantaneous pitchfork bifurcation.
This work studies front formation in the Allen-Cahn equation with a parameter heterogeneity which slowly varies in space. In particular, we consider a heterogeneity which mediates the local stability of the zero state and subsequent pitchfork bifurcation to a nontrivial state. For slowly varying ramps which are either rigidly propagating in time or stationary, we rigorously establish existence and stability of positive, monotone fronts and give leading order expansions for their interface location. For nonzero ramp speeds, and sufficiently small ramp slopes, the front location is determined by the local transition between convective and absolute instability of the base state and leads to an O(1) delay beyond the instantaneous pitchfork location before the system jumps to a nontrivial state. The slow ramp induces a further delay of the interface controlled by a slow passage through a fold of strong- and weak-stable eigenspaces of the associated linearization. We introduce projective coordinates to desingularize the dynamics near the trivial state and track relevant invariant manifolds all the way to the fold point. We then use geometric singular perturbation theory and blow-up techniques to locate the desired intersection of invariant manifolds. For stationary ramps, the front is governed by the slow passage through the instantaneous pitchfork bifurcation with inner expansion given by the unique Hastings--McLeod connecting solution of Painleve's second equation. We once again use geometric singular perturbation theory and blow-up techniques to track invariant manifolds into a neighborhood of the nonhyperbolic point where the ramp passes through zero and to locate intersections.
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