The eigentheory for nonlocal cooperative-advective system and its role in the study of free boundary system for directional epidemic models

Abstract

In this paper, we propose and analyze a nonlocal cooperative reaction--diffusion system with free boundaries and drift terms, motivated by directional epidemic spread. Lacking a variational structure but requiring sharper regularity of solutions, the model poses substantial analytical challenges compared with previous works~Du,Berestycki2016a,Berestycki2016b,Cao2019,NguyenVo2022,Tang2024a,Tang2024b. We first establish the well-posedness of the local problem and the global existence and uniqueness of classical solutions in C1 space. We then study the associated nonlocal eigenvalue problem, proving the existence, simplicity, qualitative properties, and asymptotic behavior of the principal eigenvalue. The analysis employs Fredholm theory, the Crandall--Rabinowitz bifurcation theorem, and Hadamard-type derivative formulas to describe its parameter dependence and connection with the basic reproduction number~R0. Building on this spectral characterization, we show that the system admits a sharp vanishing--spreading dichotomy in its long-term dynamics. When R01, all solutions vanish; for R0>1, the outcome depends on the initial domain size~h0 and the free-boundary expansion rate~μ. There exists a critical habitat length~ L such that if h0< L, a threshold μ>0 separates vanishing (μ∈(0,μ]) from spreading (μ>μ). In the spreading regime, solutions converge to the unique positive steady state, while in the vanishing regime they decay uniformly to zero. These results provide a rigorous framework for the threshold dynamics of cooperative--advective nonlocal systems and offer mathematical insight for further studies in epidemic modeling, ecological invasion, and population dynamics.

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