Fractional Wave Propagation in Asymmetric Nonlinear Media: Implications for Metamaterial-Based Wave Control

Document Type : Original Article

Authors

1 Department of Physics, Semnan University, Semnan 35195-363, Iran

2 Department of Physics, Qom University of Technology, Qom 1519-37195, Iran

Abstract

This study investigates the phenomenon of superarrival in Gaussian wave packets propagating through a nonlinear fractional medium under the influence of a triangular potential barrier. The time-dependent fractional Schrödinger equation is numerically solved using the Split-Step Finite Difference method to analyze the wave packet dynamics and transmission behavior in detail. The magnitude of superarrival is quantified and examined across a broad range of physical parameters, including the fractional order, nonlinearity strength, dispersion coefficient, wave packet width, initial velocity, and potential asymmetry. Results reveal that superarrival is significantly enhanced in fractional and weakly nonlinear regimes and is highly sensitive to the degree of potential asymmetry. The observed behavior reflects the interplay between nonlocality and nonlinearity, characteristic of complex and engineered materials. These insights contribute to a deeper understanding of early arrival phenomena in wave dynamics and may provide theoretical support for controlling energy or information transport in next-generation devices. Potential applications include quantum control, signal processing in photonic systems, and the design of metamaterials with tailored transmission properties at ultrafast or subwavelength scales.

Keywords

Main Subjects

References

[1]    Holm, Sverre, and Ralph Sinkus. "A unifying fractional wave equation for compressional and shear waves." The Journal of the Acoustical Society of America 127.1 (2010): 542-548.
[2]    Holm, Sverre, and Sven Peter Näsholm. "A causal and fractional all-frequency wave equation for lossy media." The Journal of the Acoustical Society of America 130.4 (2011): 2195-2202.
[3]    Prieur, Fabrice, Gregory Vilenskiy, and Sverre Holm. "A more fundamental approach to the derivation of nonlinear acoustic wave equations with fractional loss operators (L)." The Journal of the Acoustical Society of America 132.4 (2012): 2169-2172.
[4]    Uzar, Neslihan, and Sedat Ballikaya. "Investigation of classical and fractional Bose–Einstein condensation for harmonic potential." Physica A: Statistical Mechanics and its Applications 392.8 (2013): 1733-1741.
[5]    Merdan, M. "Analytical approximate solutions of fractionel convection-diffusion equation with modified Riemann-Liouville derivative by means of fractional variational iteration method." Iranian Journal of Science 37.1 (2013): 83-92.
[6]    Hosseini, Kamyar, Peyman Mayeli, and Reza Ansari. "Bright and singular soliton solutions of the conformable time-fractional Klein–Gordon equations with different nonlinearities." Waves in Random and Complex Media 28.3 (2018): 426-434.
[7]    Zhang, Jinggui. "Modulation instability of copropagating optical beams in fractional coupled nonlinear schrödinger equations." Journal of the Physical Society of Japan 87.6 (2018): 064401.
[8]    Wang, Qing, and ZhenZhou Deng. "Elliptic solitons in (1+ 2)-dimensional anisotropic nonlocal nonlinear fractional Schrödinger equation." IEEE Photonics Journal 11.4 (2019): 1-8.
[9]    Tan, Wenchang, et al. "An anomalous subdiffusion model for calcium spark in cardiac myocytes." Applied physics letters 91.18 (2007).
[10]  Herrmann, Richard. "Fractional phase transition in medium size metal clusters." Physica A: Statistical Mechanics and its Applications 389.16 (2010): 3307-3315.
[11]  Buonocore, Salvatore, and Fabio Semperlotti. "Tomographic imaging of non-local media based on space-fractional diffusion models." Journal of Applied Physics 123.21 (2018).
[12]  Hashemi, M. S. "Some new exact solutions of (2+ 1)-dimensional nonlinear Heisenberg ferromagnetic spin chain with the conformable time fractional derivative." Optical and Quantum Electronics 50.2 (2018): 79.
[13]  Medina, Leidy Y., Francisco Núñez‐Zarur, and Jhon F. Pérez‐Torres. "Nonadiabatic effects in the nuclear probability and flux densities through the fractional Schrödinger equation." International Journal of Quantum Chemistry 119.16 (2019): e25952.
[14]  Dawson, Nathan J., Onassis Nottage, and Moussa Kounta. "The second hyperpolarizability of systems described by the space-fractional Schrödinger equation." Physics Letters A 382.1 (2018): 55-59.
[15]  Hasan, Mohammad, and Bhabani Prasad Mandal. "Tunneling time in space fractional quantum mechanics." Physics Letters A 382.5 (2018): 248-252.
[16]  El-Nabulsi, Rami Ahmad. "Time-fractional Schrödinger equation from path integral and its implications in quantum dots and semiconductors." The European Physical Journal Plus 133.10 (2018): 394.
[17]  Mondol, Adreja, et al. "An insight into Newton's cooling law using fractional calculus." Journal of Applied Physics 123.6 (2018).
[18]  Kirkpatrick, Kay, and Yanzhi Zhang. "Fractional Schrödinger dynamics and decoherence." Physica D: Nonlinear Phenomena 332 (2016): 41-54.
[19]  Tayurskii, D. A., and Yu V. Lysogorskiy. "Superfluid hydrodynamic in fractal dimension space." Journal of Physics: Conference Series. Vol. 394. No. 1. IOP Publishing, 2012.
[20]  Yao, Xiankun, and Xueming Liu. "Solitons in the fractional Schrödinger equation with parity-time-symmetric lattice potential." Photonics Research 6.9 (2018): 875-879.
[21]  Li, Pengfei, et al. "PT-symmetric optical modes and spontaneous symmetry breaking in the space-fractional Schrödinger equation." Rom. Rep. Phys 71.2 (2019): 106.
[22]  Zhan, Kaiyun, et al. "Defect modes of defective parity-time symmetric potentials in one-dimensional fractional Schrödinger equation." IEEE Photonics Journal 9.6 (2017): 1-8.
[23]  Huang, Changming, et al. "Localization and Anderson delocalization of light in fractional dimensions with a quasi-periodic lattice." Optics Express 27.5 (2019): 6259-6267.
[24]  Zhang, Y., et al. "Diffraction free beams in fractional Schrödinger equation, Sci." Rep. (UK) 6 (2016): 1-8.
[25]  Stickler, B. A. "Potential condensed-matter realization of space-fractional quantum mechanics: The one-dimensional Lévy crystal." Physical Review E—Statistical, Nonlinear, and Soft Matter Physics 88.1 (2013): 012120.
[26]  Zhang, Da, et al. "Unveiling the link between fractional Schrödinger equation and light propagation in honeycomb lattice." Annalen der Physik 529.9 (2017): 1700149.
[27]  Huang, Xianwei, Zhixiang Deng, and Xiquan Fu. "Dynamics of finite energy Airy beams modeled by the fractional Schrödinger equation with a linear potential." Journal of the Optical Society of America B 34.5 (2017): 976-982.
[28]  Huang, Xianwei, et al. "Propagation characteristics of ring Airy beams modeled by fractional Schrödinger equation." Journal of the Optical Society of America B 34.10 (2017): 2190-2197.
[29]  Zang, Feng, Yan Wang, and Lu Li. "Self-induced periodic interfering behavior of dual Airy beam in strongly nonlocal medium." Optics Express 27.10 (2019): 15079-15090.
[30]  Zhang, Yiqi, et al. "Optical Bloch oscillation and Zener tunneling in the fractional Schrödinger equation." Scientific Reports 7.1 (2017): 17872.
[31] Wang, Qing, et al. "Hermite-gaussian–like soliton in the nonlocal nonlinear fractional Schrödinger equation." Europhysics Letters 122.6 (2018): 64001.
[32] Chen, Manna, et al. "Optical solitons, self-focusing, and wave collapse in a space-fractional Schrödinger equation with a Kerr-type nonlinearity." Physical Review E 98.2 (2018): 022211.
[33] Huang, Changming, et al. "Gap solitons in fractional dimensions with a quasi‐periodic lattice." Annalen der Physik 531.9 (2019): 1900056.
[34] Yao, Xiankun, and Xueming Liu. "Off-site and on-site vortex solitons in space-fractional photonic lattices." Optics Letters 43.23 (2018): 5749-5752.
[35] Meng, Yunji, et al. "Self-splitting of spatial solitons in a nonlinear fractional Schrödinger equation with a longitudinal potential barrier." Optics Communications 440 (2019): 68-74.
[36] Zhang, Lifu, et al. "Propagation dynamics of super-Gaussian beams in fractional Schrödinger equation: from linear to nonlinear regimes." Optics express 24.13 (2016): 14406-14418.
[37] Dong, Liangwei, and Changming Huang. "Double-hump solitons in fractional dimensions with a 𝒫𝒯–symmetric potential." Optics Express 26.8 (2018): 10509-10518.
 
[37] Dong, Liangwei, and Changming Huang. "Double-hump solitons in fractional dimensions with a 𝒫𝒯–symmetric potential." Optics Express 26.8 (2018): 10509-10518.
 
[38] Amadou, Yaouba, et al. "Fractional effects on solitons in a 1D array of rectangular ferroelectric nanoparticles." Waves in Random and Complex Media 30.3 (2020): 581-592.
[39] Forbes, Richard G., and Jonathan HB Deane. "Transmission coefficients for the exact triangular barrier: an exact general analytical theory that can replace Fowler & Nordheim's 1928 theory." Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences 467.2134 (2011): 2927-2947.
[40] Zhao, Zijun C., and David R. McKenzie. "Antireflection coating of barriers to enhance electron tunnelling: exploring the matter wave analogy of superluminal optical phase velocity." Scientific reports 7.1 (2017): 12772.
[41] Chandra, Amitabh, and Lester F. Eastman. "Quantum mechanical reflection at triangular``planar-doped''potential barriers for transistors." Journal of Applied Physics 53.12 (1982): 9165-9169.
[42]  Leite, Telio Nobre, and Helinando Pequeno de Oliveira. "Tunneling processes in a triangular multibarrier semiconductor heterostructure." IEEE transactions on electron devices 58.3 (2011): 716-719.
[43]  Mahajan, Ashutosh, and Swaroop Ganguly. "An analytical model for electron tunneling in triangular quantum wells." Semiconductor Science and Technology 36.5 (2021): 055012.
[44]  Ohmukai, Masato. "Triangular double barrier resonant tunneling." Materials Science and Engineering: B 116.1 (2005): 87-90.
[45]  Mekkaoui, Miloud, Ahmed Jellal, and Hocine Bahlouli. "Tunneling of electrons in graphene via double triangular barrier in external fields." Solid State Communications 358 (2022): 114981.
[46]  Chandra, Amitabh, and Lester F. Eastman. "Quantum mechanical reflection at triangular``planar doped ''potential barriers for transistors." Journal of Applied Physics 53.12 (1982): 9165-9169.
[47]  Wang, Gangwei, and Tianzhou Xu. "Optical soliton of time fractional Schrödinger equations with He’s semi-inverse method." Laser Physics 25.5 (2015): 055402.
[48]  Rida, S. Z., H. M. El-Sherbiny, and A. A. M. Arafa. "On the solution of the fractional nonlinear Schrödinger equation." Physics Letters A 372.5 (2008): 553-558.
[49] Khater, Mostafa MA, Aly R. Seadawy, and Dianchen Lu. "New optical soliton solutions for nonlinear complex fractional Schrödinger equation via new auxiliary equation method and novel (G'/G) (G′/G)-expansion method." Pramana 90 (2018): 1-20.
[50] Zayed, Elsayed ME, and Abdul-Ghani Al-Nowehy. "The ϕ 6-model expansion method for solving the nonlinear conformable time-fractional Schrödinger equation with fourth-order dispersion and parabolic law nonlinearity." Optical and Quantum Electronics 50.3 (2018): 164.
[51] Zhang, Hui, et al. "Crank–Nicolson Fourier spectral methods for the space fractional nonlinear Schrödinger equation and its parameter estimation." International Journal of Computer Mathematics 96.2 (2019): 238-263.
[52] Wang, Dongling, Aiguo Xiao, and Wei Yang. "A linearly implicit conservative difference scheme for the space fractional coupled nonlinear Schrödinger equations." Journal of Computational Physics 272 (2014): 644-655.
[53] Li, Meng, et al. "A fast linearized conservative finite element method for the strongly coupled nonlinear fractional Schrödinger equations." Journal of Computational Physics 358 (2018): 256-282.
[54] Khan, Najeeb Alam, Muhammad Jamil, and Asmat Ara. "Approximate solutions to time‐fractional Schrödinger equation via homotopy analysis method." International Scholarly Research Notices 2012.1 (2012): 197068.
[55] Wang, Pengde, and Chengming Huang. "Split-step alternating direction implicit difference scheme for the fractional Schrödinger equation in two dimensions." Computers & Mathematics with Applications 71.5 (2016): 1114-1128.
[56] Zhang, Yiqi, et al. "Optical Bloch oscillation and Zener tunneling in the fractional Schrödinger equation." Scientific Reports 7.1 (2017): 17872.
[57] Hasan, Mohammad, and Bhabani Prasad Mandal. "Tunneling time in space fractional quantum mechanics." Physics Letters A 382.5 (2018): 248-252.
[58] Li, Meng. "A high-order split-step finite difference method for the system of the space fractional CNLS." The European Physical Journal Plus 134.5 (2019): 244.
[59] Solaimani, M. "Nontrivial wave-packet collision and broadening in fractional Schrodinger equation formalism." Journal of Modern Optics 67.12 (2020): 1128-1137.
[60] Farag, Neveen GA, et al. "Numerical Solutions of the (2+ 1)-Dimensional Nonlinear and Linear Time-Dependent Schrödinger Equations Using Three Efficient Approximate Schemes." Fractal and Fractional 7.2 (2023): 188.
[61] Li, Meng. "A high-order split-step finite difference method for the system of the space fractional CNLS." The European Physical Journal Plus 134.5 (2019): 244.
[62] Nizam, Elminur, and Kaysar Rahman. "A Compact Split-step Finite Difference Method for Solving the Nonlinear Schrödinger Equation." Journal of Physics: Conference Series. Vol. 2660. No. 1. IOP Publishing, 2023.
[63] Zhu, Pengfei, Lan Wang, and Qiang Li. "High order compact split step finite difference method for two-dimensional coupled nonlinear Schrödinger system." Journal of Physics: Conference Series. Vol. 2202. No. 1. IOP Publishing, 2022.
[64] Vatan, M., et al. "Transport properties of a traveling wave packet through rectangular quantum wells and barriers." Optik 136 (2017): 281-288.
[65] Solaimani, M. "Nontrivial wave-packet collision and broadening in fractional Schrodinger equation formalism." Journal of Modern Optics 67.12 (2020): 1128-1137.
[66] Bandyopadhyay, Somshubhro, A. S. Majumdar, and Dipankar Home. "Quantum-mechanical effects in a time-varying reflection barrier." Physical Review A 65.5 (2002): 052718.
 
Progress in Physics of Applied Materials
Volume 5, Issue 2 - Serial Number 9
November 2025
Pages 107-116

Files

History

  • Receive Date: 06 June 2025
  • Revise Date: 14 July 2025
  • Accept Date: 18 July 2025

Share

How to cite

Statistics