The Stretched Horizon Limit

TL;DR

This paper analyzes gravitational perturbations near a cosmological horizon in de Sitter space with a boundary, revealing a hierarchy of modes and fluid-like behavior, and discusses universal features of horizon dynamics.

Contribution

It provides a detailed linearized perturbation analysis near a cosmological horizon, uncovering new boundary modes and establishing a fluid-dynamical interpretation with universal properties.

Findings

Discovery of boundary gapless and soft modes near the horizon.

Identification of fluid-dynamical modes with specific viscosity ratios.

Universal Rindler geometry governs horizon dynamics in a certain scaling regime.

Abstract

We consider four-dimensional general relativity with a positive cosmological constant, $\Lambda$, in the presence of a boundary, $\Gamma$, of finite spatial size. The boundary is located near a cosmological event horizon, and is subject to boundary conditions that fix the conformal class of the induced metric, and, $K$, the trace of the extrinsic curvature along $\Gamma$. The proximity of $\Gamma$ to the horizon is controlled by the dimensionless parameter ${K}{{\Lambda}^{-\frac{1}{2}}}$. We provide an exhaustive analysis of linearised gravitational perturbations for the setup. This is performed both for a $\Gamma$ encasing a portion of the static patch that ends just before the cosmological horizon (pole patch), as well as a $\Gamma$ containing only the region near the cosmological horizon (cosmic patch). In the pole patch, we uncover a layered hierarchy of modes: ordinary normal modes, a novel type of boundary gapless mode, and boundary soft modes of frequency $\omega \approx \pm 2\pi i T_{\text{dS}}$, with $T_{\text{dS}}$ the horizon temperature. Minkowskian behaviour is recovered only for angular momenta $l \gtrsim {K}{{\Lambda}^{-\frac{1}{2}}}$ which can be made parametrically large, thus attenuating previously found growing modes. In the cosmic patch, we uncover sound and shear fluid-dynamical modes that we interpret in terms of a conformal fluid with shear viscosity over entropy density ratio $\tfrac{\eta}{s} = \tfrac{1}{4\pi}$ and vanishing bulk viscosity $\zeta=0$. The fluid dynamical sector is shown to admit a non-linear treatment. We describe a scaling regime in which the stretched horizon gravitational dynamics is dictated by a universal Rindler geometry, independent to the details of the infilling horizon. We briefly discuss quantitative features that distinguish cosmological and black hole horizons away from the Rindler regime.