Edge currents for the time-fractional, half-plane, Schrodinger equation with constant magnetic field

Peter D. Hislop, Eric Soccorsi

Published 2024-01-13Version 1

We study the large-time asymptotics of the edge current for a family of time-fractional Schrodinger equations with a constant, transverse magnetic field on a half-plane $(x,y) \in \mathbb{R}_x^+ \times \mathbb{R}_y$. The TFSE is parameterized by two constants $(\alpha, \beta)$ in $(0,1]$, where $\alpha$ is the fractional order of the time derivative, and $\beta$ is the power of $i$ in the Schrodinger equation. We prove that for fixed $\alpha$, there is a transition in the transport properties as $\beta$ varies in $(0,1]$: For $0 < \beta < \alpha$, the edge current grows exponentially in time, for $\alpha = \beta$, the edge current is asymptotically constant, and for $\beta > \alpha$, the edge current decays in time. We prove that the mean square displacement in the $y\in \mathbb{R}$-direction undergoes a similar transport transition. These results provide quantitative support for the comments of Laskin \cite{laskin2000_1} that the latter two cases, $\alpha = \beta$ and $\alpha < \beta$, are the physically relevant ones.