The move from Fujita to Kato type exponent for a class of semilinear evolution equations with time-dependent damping (2008.10374v1)

Abstract: In this paper, we derive suitable optimal $L^p-L^q$ decay estimates, $1\leq p\leq 2\leq q\leq \infty$, for the solutions to the $\sigma$-evolution equation, $\sigma>1$, with scale-invariant time-dependent damping and power nonlinearity~$|u|^p$, [ u_{tt}+(-\Delta)^\sigma u + \frac{\mu}{1+t} u_t= |u|^{p}, ] where $\mu>0$, $p>1$. The critical exponent $p=p_c$ for the global (in time) existence of small data solutions to the Cauchy problem is related to the long time behavior of solutions, which changes accordingly $\mu \in (0, 1)$ or $\mu>1$. Under the assumption of small initial data in $L^1\cap L^2$, we find the critical exponent [ p_c=1+ \max \left{\frac{2\sigma}{[n-\sigma+\sigma\mu]+}, \frac{2\sigma}{n} \right} =\begin{cases} 1+ \frac{2\sigma}{[n-\sigma+\sigma\mu]+}, \quad \mu \in (0, 1)\ 1+ \frac{2\sigma}{n}, \quad \mu>1. \end{cases} ] For $\mu>1$ it is well known as Fujita type exponent, whereas for $\mu \in (0, 1)$ one can read it as a shift of Kato exponent.