English

Black-Hole Radiation Decoding is Quantum Cryptography

Quantum Physics 2023-05-23 v2 Cryptography and Security

Abstract

We propose to study equivalence relations between phenomena in high-energy physics and the existence of standard cryptographic primitives, and show the first example where such an equivalence holds. A small number of prior works showed that high-energy phenomena can be explained by cryptographic hardness. Examples include using the existence of one-way functions to explain the hardness of decoding black-hole Hawking radiation (Harlow and Hayden 2013, Aaronson 2016), and using pseudorandom quantum states to explain the hardness of computing AdS/CFT dictionary (Bouland, Fefferman and Vazirani, 2020). In this work we show, for the former example of black-hole radiation decoding, that it also implies the existence of secure quantum cryptography. In fact, we show an existential equivalence between the hardness of black-hole radiation decoding and a variety of cryptographic primitives, including bit-commitment schemes and oblivious transfer protocols (using quantum communication). This can be viewed (with proper disclaimers, as we discuss) as providing a physical justification for the existence of secure cryptography. We conjecture that such connections may be found in other high-energy physics phenomena.

Keywords

Cite

@article{arxiv.2211.05491,
  title  = {Black-Hole Radiation Decoding is Quantum Cryptography},
  author = {Zvika Brakerski},
  journal= {arXiv preprint arXiv:2211.05491},
  year   = {2023}
}
R2 v1 2026-06-28T05:35:26.127Z