Global Existence and Finite-Time Blow-Up of Solutions for Parabolic Equations Involving the Fractional Musielak $g_{x,y}$-Laplacian

Abstract: In this work, we study the parabolic fractional Musielak $g_{x,y}$-Laplacian equation: \begin{equation*} \left{ \begin{aligned} u_{t} + (-\Delta){{g}{x,y}}^{s} u &= f(x,u), && \text{in } \Omega \times (0, \infty), u &= 0, && \text{on } \mathbb{R}^N \setminus \Omega \times (0, \infty), u(x,0) &= u_0(x), && \text{in } \Omega, \end{aligned} \right. \end{equation*} where $(-\Delta){{g}{x,y}}^{s}$ denotes the fractional Musielak $g_{x,y}$-Laplacian, and $f$ is a Carath\'eodory function satisfying subcritical growth conditions. Using the modified potential well method and Galerkin's method, we establish results on the local and global existence of weak and strong solutions, as well as finite-time blow-up, depending on the initial energy level (low, critical, or high). Moreover, we explore a class of nonlocal operators to highlight the broad applicability of our approach. This study contributes to the developing theory of fractional Musielak-Sobolev spaces, a field that has received limited attention in the literature. To our knowledge, this is the first work addressing the parabolic fractional $g_{x,y}$-Laplacian equation.