A dimension-independent critical exponent in a nutrient taxis system
Abstract: In a ball $Ω\subset Rn$ with arbitrary $n\ge 1$, the chemotaxis-consumption system [ \left{ \begin{array}{l} u_t = \nabla \cdot \big(D(u)\nabla u\big) - \nabla \cdot (u\nabla v), \[1mm] 0 = Δv - uv, \end{array} \right. ] is considered under no-flux boundary conditions for $u$, and for prescribed constant positive boundary data for $v$. Under the assumption that $D\in C3([0,\infty))$ satisfies [ D(ξ)\ge k_D (ξ+1){-α} \qquad \mbox{for all } ξ\ge 0 \qquad \qquad (\star) ] with some $α<1$ and some $k_D>0$, it is shown that for each nonnegative and radially symmetric $u_0\in \bigcup_{q>\max{2,n}} W{1,q}(Ω)$, a uniquely determined global bounded classical solution exists. This complements a previous result according to which given any positive $D\in C3([0,\infty))$ fulfilling $D(ξ) \le K_D (ξ+1){-α}$ with some $α>1$ and $K_D>0$, one can find nonnegative radial initial data $u_0\in C_0\infty(Ω)$ such that no global solution exists.
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