A Schwinger-Keldysh Formulation of Semiclassical Operator Dynamics

In this work we develop a real-time Schwinger-Keldysh formulation of Krylov dynamics that treats Krylov complexity as an in-in observable generated by a closed time contour path integral. The resulting generating functional exposes an emergent phase-space description in which the Lanczos coefficients define an effective Hamiltonian governing operator motion along the Krylov chain. In the semiclassical limit, exponential complexity growth arises from hyperbolic trajectories, and asymptotically linear Lanczos growth appears as a universal chaotic fixed point, with sub-leading deformations classified as irrelevant, marginal or relevant. Going beyond the saddle, the Schwinger-Keldysh framework provides controlled access to fluctuations and large deviations of Krylov complexity, revealing sharp signatures of integrability-chaos crossovers that are invisible at the level of the mean. This formulation reorganises Krylov complexity into a dynamical field-theoretic framework and identifies new fluctuation diagnostics of operator growth in closed quantum systems.

💡 Research Summary

The paper presents a novel formulation of Krylov complexity (KC) using the real‑time Schwinger‑Keldysh (SK) closed‑time‑contour path integral. Starting from the standard operator‑Hilbert‑Schmidt inner product, the authors recast Heisenberg evolution of a seed operator (O_0) into a tight‑binding problem on a semi‑infinite “Krylov chain”. The Liouvillian (L=