Page Curves and Bath Deformations

Abstract: We study the black hole information problem within a semiclassically gravitating AdS d black hole coupled to and in equilibrium with a d-dimensional thermal conformal bath. We deform the bath state by a relevant scalar deformation, triggering a holographic RG flow whose "trans-IR" region deforms from a Schwarzschild geometry to a Kasner universe. The setup manifests two independent scales which control both the extent of coarse-graining and the entanglement dynamics when counting Hawking degrees of freedom in … Show more

“…While a T is stationary at both the boundary (the UV) and the horizon (the IR), it is still monotonic even along the trans-IR flow, thus satisfying an extension of the holographic a-theorem [9,10] to complex energy scales. With emphasis on "free Kasner flows" [1,11], we find a T → 0 at the singularity (the trans-IR endpoint). In other words, all degrees of freedom are lost at the singularity.…”

“…6 Furthermore r < r h is the exterior (F (r) > 0), while r > r h is the interior (F (r) < 0). The resulting metric is the Schwarzschildlike one of [1,11],…”

“…Thus, we can answer (Q2) by analyzing how the near-singularity geometry is affected by backreaction. Describing backreaction is more easily done after specifying the matter sector, so we focus on the minimal model of [1,11]-Einstein gravity with a free massive scalar. In the resulting flows, we will find that a T → 0 at the singularity, around which the local geometry is that of a Kasner universe [32][33][34].…”

“…To solve ( 25)-( 27) numerically, we expand {F, χ, φ} around the horizon r = r h then perform a two-sided shooting method towards both the boundary r = 0 and the singularity r = ∞. The mathematical details are in [11]. The near-singularity geometry is a Kasner universe,…”

“…This expression is more meaningful if it is written in terms of the Kasner exponent p t , which is directly related to q in the literature [1,11]. For any d,…”

Trans-IR Flows to Black Hole Singularities

“…While a T is stationary at both the boundary (the UV) and the horizon (the IR), it is still monotonic even along the trans-IR flow, thus satisfying an extension of the holographic a-theorem [9,10] to complex energy scales. With emphasis on "free Kasner flows" [1,11], we find a T → 0 at the singularity (the trans-IR endpoint). In other words, all degrees of freedom are lost at the singularity.…”

“…6 Furthermore r < r h is the exterior (F (r) > 0), while r > r h is the interior (F (r) < 0). The resulting metric is the Schwarzschildlike one of [1,11],…”

“…Thus, we can answer (Q2) by analyzing how the near-singularity geometry is affected by backreaction. Describing backreaction is more easily done after specifying the matter sector, so we focus on the minimal model of [1,11]-Einstein gravity with a free massive scalar. In the resulting flows, we will find that a T → 0 at the singularity, around which the local geometry is that of a Kasner universe [32][33][34].…”

“…To solve ( 25)-( 27) numerically, we expand {F, χ, φ} around the horizon r = r h then perform a two-sided shooting method towards both the boundary r = 0 and the singularity r = ∞. The mathematical details are in [11]. The near-singularity geometry is a Kasner universe,…”

“…This expression is more meaningful if it is written in terms of the Kasner exponent p t , which is directly related to q in the literature [1,11]. For any d,…”

Trans-IR Flows to Black Hole Singularities

Path integral complexity and Kasner singularities

Entropy of radiation with dynamical gravity