Pith. sign in

Glimpses of black hole formation/evaporation in highly inelastic, ultra-planckian string collisions

2 Pith papers cite this work. Polarity classification is still indexing.

2 Pith papers citing it
abstract

We revisit possible glimpses of black-hole formation by looking at ultra-planckian string-string collisions at very high final-state multiplicity. We compare, in particular, previous results using the optical theorem, the resummation of ladder diagrams at arbitrary loop order, and the AGK cutting rules, with the more recent study of $2 \rightarrow N$ scattering at $N \sim s M_P^{-2} \gg 1$. We argue that some apparent tension between the two approaches disappears once a reinterpretation of the latter's results in terms of suitably defined infrared-safe cross sections is adopted. Under that assumption, the typical final state produced in an ultra-planckian collision does indeed appear to share some properties with those expected from the evaporation of a black hole of mass $\sqrt{s}$, although no sign of thermalization is seen to emerge at this level of approximation.

citation-role summary

background 1

citation-polarity summary

fields

hep-th 2

years

2026 2

verdicts

UNVERDICTED 2

roles

background 1

polarities

background 1

representative citing papers

Negative running of gravitational positivity

hep-th · 2026-03-16 · unverdicted · novelty 7.0

Non-minimal three-point interactions induce negative one-loop running of Wilson coefficients in gravitational EFTs, yet graviton loops generate positive IR contributions that dominate the bounds after smearing if the species number is bounded.

citing papers explorer

Showing 2 of 2 citing papers.

  • Negative running of gravitational positivity hep-th · 2026-03-16 · unverdicted · none · ref 98 · internal anchor

    Non-minimal three-point interactions induce negative one-loop running of Wilson coefficients in gravitational EFTs, yet graviton loops generate positive IR contributions that dominate the bounds after smearing if the species number is bounded.

  • Rethinking quantum information in gravity and fields hep-th · 2026-06-29 · unverdicted · none · ref 220 · internal anchor

    The paper organizes important open questions in quantum gravity and quantum information into four themes without presenting new results or derivations.