Quantum Fast-Forwarding Beyond Reversibility: The α-Perturbed n-Cycle

Abstract

Quantum fast-forwarding (QFF) is usually formulated for reversible Markov chains, where the projected quantum walk evolution is exactly governed by Chebyshev polynomials of a Hermitian discriminant matrix. We study whether this framework can be extended to nonreversible dynamics for an α-perturbed n-cycle Markov chain, which preserves circulant structure while introducing controlled irreversibility. We show that the nonreversible case has a fundamental obstruction: for α≠ 0, the eigenvalues of Pα leave the interval [-1,1], so Tm(Pα) is not uniformly bounded and cannot arise as an exact unitary compression for all times. Thus, exact Chebyshev-based QFF does not extend directly beyond reversibility. Nevertheless, we obtain a finite-time approximation result using truncated Chebyshev and LCU techniques. The evolution Pαt can be approximated with degree τ=O(|α|t+t(t/η)), which recovers the reversible O( t) behavior only in the perturbative regime |α|=O(t-1/2). This identifies a nearly reversible regime where QFF survives perturbatively and quantifies how irreversibility degrades the speedup.