Cosmological Pseudo-Entropy

Abstract

We study pseudo entropy S, a recent generalization of entanglement entropy, for scalar cosmological perturbations in de Sitter space with sound speed 0.024 ≤ cs ≤ 1, and in expanding and contracting FLRW backgrounds with varying equation-of-state parameter w. In de Sitter space, Re(S) grows after horizon exit while cs controls its onset and saturates at late times. A similar saturation occurs in expanding-accelerating and contracting-decelerating backgrounds. In contrast, expanding-decelerating and contracting-accelerating backgrounds show large early-time Re(S) followed by oscillations after horizon re-entry. This happens because while the squeezing freezes, the squeezing angle doesn't. Unlike entanglement entropy, pseudo entropy possesses an imaginary part, Im(S), as well, which can encode the relative phase. Im(S) decays to zero in de Sitter and expanding-accelerating cases, but forms dense sub-Hubble oscillation bands in expanding-decelerating and contracting-accelerating backgrounds. Compared with entanglement entropy, Krylov complexity, and Nielsen circuit complexity, pseudo entropy captures otherwise hidden phase information; in the unsaturated regime, its slope is 2 times that of Nielsen complexity. Unlike circuit complexity, whose saturation bound is w-independent, pseudo entropy is sensitive to w during the transition regime, making it a finer information theoretic diagnostic of cosmological dynamics.