Approximation Analysis of a Parabolic-Parabolic Chemotaxis Model with Logarithmic Nonlinearity
Abstract
We consider the Keller-Segel system with logical source align* cases ut = ∇ · (φ(u)∇ u) - ∇ · ((u)∇ v)+f(u), & x ∈ , \; t > 0, vt = v - v + u, & x ∈ , \; t > 0, cases align* in a smooth bounded domain \( ⊂ Rn\) with \(n ≥ 2\), the Neumann initial-boundary value problem admits a globally defined, uniformly bounded classic solution for all sufficiently regular non-negative initial data \(u0\) and \(v0\). In the first equation, assume that \(φ\) and \(\) are dominated by a logarithmic function and a polynomial respectively. The logical source \(f\) representing the natural growth and decay of cells satisfies \(f ∈ W1,∞loc()\) and \(f(0) ≥ 0\). Then we will see that the unique solution \(u ∈ C2,1(() × [0,T] )\) and \(v ∈ W1,q([0,T] ; C2,1())\).
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