Cosmological brick walls & quantum chaotic dynamics of de Sitter horizons

TL;DR

This paper investigates quantum chaotic dynamics of de Sitter horizons using the brick wall model, analyzing scalar field spectra and revealing signatures of chaos through spectral form factor and Krylov complexity.

Contribution

It applies the brick wall model to de Sitter spacetimes, revealing chaos signatures in scalar spectra and clarifying diagnostics beyond level repulsion.

Findings

Pure de Sitter spectrum shows long-range chaos signatures without Wigner-Dyson distribution.

Schwarzschild-de Sitter spectrum is a superposition of two near-horizon sectors, affecting level-spacing.

Spectral form factor and Krylov complexity reveal chaos even with non-standard spectral features.

Abstract

Originally proposed by 't Hooft, the brick wall model has recently reemerged as a useful framework for probing quantum aspects of horizon physics, particularly in the context of holography. In this paper, we apply it to asymptotically de Sitter spacetimes. We compute the normal modes of a massless scalar field in pure de Sitter space and in the Schwarzschild-de Sitter black hole, and analyze the resulting single-particle spectra using the level-spacing distribution, the spectral form factor, and Krylov complexity. In pure de Sitter, the spectrum exhibits clear long-range signatures of chaos despite not obeying a conventional Wigner-Dyson level-spacing distribution. The Schwarzschild-de Sitter case is qualitatively richer: in the WKB regime, where tunneling between the two classically allowed regions is exponentially suppressed, the presence of both an event horizon and a cosmological horizon gives rise to two independent near-horizon sectors, so that the full spectrum is the superposition of two subsequences. As a result, the combined level-spacing distribution develops a nonzero value at $s=0$ even when spectral correlations remain. Nevertheless, for sufficiently small stretched-horizon fluctuations, the superposed spectrum still exhibits an approximately linear ramp in the spectral form factor and a pronounced peak in Krylov complexity. Our results show that the absence of strict level repulsion should not, by itself, be taken as evidence against chaos, and that the spectral form factor and Krylov complexity provide sharper diagnostics of the underlying chaotic dynamics.