Phase Diagrams of Information Backflow: Unifying Entanglement Revivals and Entropy Overshoots in Minimal Non-Markovian Models

Abstract

Memory effects in non-Markovian dynamics are often diagnosed either via quantum-correlation revivals or via non-monotonic classical information measures, yet a unified minimal framework comparing their ``backflow phases'' is still lacking. Here we propose an information-backflow phase-diagram approach that places quantum entanglement revivals and classical entropy overshoots on the same footing through a common backflow functional NI=∫ I>0 I\,dt. On the quantum side, we employ a fractional (Caputo) extension of a two-state dissipative model embedded by thermo-field dynamics (TFD), yielding a closed-form intrinsic entanglement component b(α)qe(t)=14[Eα(-λα tα)]22(ω t) and an integrated revival measure Nqe that delineates a sharp boundary near α 1/2 in the (α,ω/λ) plane. On the classical side, we consider a three-state model whose Markov generator is promoted either to an exponential-kernel generalized master equation (with exact Markov embedding) or to a semi-Markov process with Erlang-2 waiting times. We quantify non-monotonicity by the entropy overshoot H and KL-based diagnostics on the probability simplex. To strengthen the quantum--classical symmetry, we further introduce a fractional Mittag--Leffler memory kernel in the classical dynamics and show that an analogous backflow transition emerges around α 1/2, indicating that the boundary originates from the kernel's mathematical structure rather than from quantumness per se. Overall, our results provide a compact, model-agnostic route to classify non-Markovianity by phase diagrams of information backflow and to interpret them via a shared embedding narrative: memory stored in hidden degrees of freedom returns to the observed sector as non-monotonic information flow.