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 this framework to explore a particle in a periodic potential, where the Schrodinger equation is extended to its fractional form. This allows us to study how the Levy index q governs the formation and inversion of energy bands, offering a pathway to engineer new physical behaviors by tuning q in periodic quantum systems. We solve the fractional Schrodinger equation (FSE) for periodic rectangular potentials of varying height V0, barrier thickness L, and well width W using an imaginary-time evolution algorithm, supplemented by Gaussian process regression. This analysis reveals a qualitative shift in the system's band structure at q = 2, separating into distinct regimes of dispersion for q > 2 and q < 2. For q > 2, the energy bands invert as symmetric minima emerge within the first Brillouin zone and shift from k = 0 toward k= π/a with increasing q. These degenerate minima define a Bloch-momentum qubit, suggesting an analog to valley degrees of freedom in valleytronics. The q at which inversion completes scales as q V0-0.280.05, q L-0.350.08, and q W-0.490.06 when varying parameters individually, indicating a tunable sensitivity to potential geometry. In contrast, for q < 2, the ground band hardens around k = 0, with a dispersion following C|k|q+E0 near k = 0. This suggests an effective mass of 0 for 1<q<2 at the band's lowest energy state. These results demonstrate that the Levy index serves as a tunable degree of freedom in quantum periodic systems, capable of driving band inversion, modulating the band gap, and reshaping carrier dynamics through effective-mass control.

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