Tunable Bands in 1D Fractional Quantum Media

Abstract

Fractional calculus has become an essential framework in geophysics, optics, and biological systems to capture long-range correlations and anomalous transport. In this article, we extend fractional calculus to explore a particle in a periodic potential, where the Schrödinger equation is generalized to its fractional form. This framework allows us to study how the Lévy index $q$ governs the formation and inversion of energy bands, offering a pathway to engineer new physical behaviors and device functionalities by tuning $q$ in periodic quantum systems. We solve the fractional Schrödinger equation for periodic rectangular potentials of varying height $V_0$, barrier thickness $L$, and well width $W$ using an imaginary-time evolution algorithm, and supplement the discrete energy dispersion through Gaussian process regression. Our analysis reveals a qualitative shift in the band structure at $q=2$, separating into regimes for $q>2$ and $q<2$. For $q > 2$, energy bands undergo an inverting transformation as symmetric minima emerge within the first Brillouin zone, shifting from $k=0$ toward $k=\pm π/a$ with increasing $q$. These degenerate minima define a Bloch-momentum qubit, suggesting an analog to valley degrees of freedom used in valleytronics. The response of the ground band scales with fractional order as $V_0^{-0.28\pm0.05}L^{-0.34\pm0.08}W^{-0.49\pm0.06}$, indicating tunable sensitivity to geometry. For $q < 2$, the effective mass near $k = 0$ decreases exponentially with $q$, yielding a universal effective mass of $0.15\pm0.01$ as $q \to 1$, demonstrating that the Lévy index serves as a tunable degree of freedom capable of driving band inversion, modulating the band gap, and reshaping carrier dynamics.