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Discrete-Time Quantum Random Walk for Epidemiological Modeling

Quantum Physics 2025-09-15 v2

Abstract

We introduce a discrete-time quantum random walk (QRW) framework for spatial epidemic modelling on a two-dimensional square lattice and compare its dynamics to classical random-walk SIR models. In our model, each infected site spawns a quantum walker whose coherent evolution (controlled by an amplitude-splitting coin and conditional shifts) can infect visited susceptible sites with probability pp and persists for a lifetime of τ\tau steps. We perform extensive quantum simulations on finite lattices and compute the basic reproduction number R0R_0 across a broad grid of (p,τ)(p,\tau) values. Results show that QRW dynamics interpolate between diffusive and super-diffusive regimes: at low pp the QRW reproduces classical-like R0R_0, while at higher pp and τ\tau ballistic propagation and interference produce markedly larger R0R_0 and non-Gaussian spatial profiles. We compare the QRW R0R_0 range to empirical estimates from historical outbreaks and discuss parameter regimes where QRW offers a closer qualitative match than classical diffusion. We conclude that QRWs provide a flexible, conceptually novel toy model for exploring rapid or heavy-tailed epidemic spread.

Keywords

Cite

@article{arxiv.2509.05795,
  title  = {Discrete-Time Quantum Random Walk for Epidemiological Modeling},
  author = {Sayan Manna and Nikhil Kowshik and Sudebkumar Prasant Pal},
  journal= {arXiv preprint arXiv:2509.05795},
  year   = {2025}
}

Comments

22 pages, 34 figures

R2 v1 2026-07-01T05:24:34.315Z