Population–Coherence Routes to Purity in Page-Type Models of Black-Hole Evaporation
José J. Gil

TL;DR
This paper explores how purity in black-hole evaporation can be achieved through coherence rather than population in quantum states.
Contribution
The paper introduces a novel framework using population–coherence decomposition to analyze purity in Page-type black-hole evaporation models.
Findings
A geometric representation in a population–coherence plane distinguishes different routes to purity.
Late-time purity recovery in radiation is shown to be coherence-dominated under uniform population assumptions.
Explicit families of states demonstrate opposite internal structures with identical spectra and global purity.
Abstract
We revisit the black-hole information problem from the viewpoint of a population–coherence decomposition of density-matrix purity. Building on a previously developed formalism for n-dimensional density matrices, we characterize each state by a normalized global purity index and two complementary indices, which quantify the contributions of level populations and coherences. This yields a simple quadratic relation and a geometric representation in a “population–coherence plane”, where different routes to purity can be distinguished. In the two-level case, we construct explicit families of states with identical spectra and global purity but opposite internal structure, realizing population-dominated and coherence-dominated routes. We then apply this framework to a standard Page-type evaporation model without an explicit Hamiltonian, in which a black hole and its Hawking radiation form a…
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Taxonomy
TopicsBlack Holes and Theoretical Physics · Noncommutative and Quantum Gravity Theories · Particle physics theoretical and experimental studies
