English

On Interstellar Quantum Communication and the Fermi Paradox

Quantum Physics 2024-08-06 v1 Instrumentation and Methods for Astrophysics

Abstract

Since it began \cite{CocconiMorrison}, the search for extraterrestrial intelligence (SETI) has focused on interstellar \emph{classical} communication. Recently, Berera \cite{Berera:2020rpl} pointed out that, at certain frequencies, photon qubits can retain their quantum coherence over interstellar (and even intergalactic) distances, raising the prospect of interstellar \emph{quantum} communication. This is an intriguing possibility, since quantum communication permits certain tasks that would be impossible with classical communication, and allow exponential speed-ups for others. (We suggest some motivations in the interstellar context.) But quantum coherence alone is not sufficient for quantum communication: here, for the first time, we analyze the \emph{quantum capacity} QQ of an interstellar channel. We point out that, to have non-zero quantum capacity Q>0Q>0, interstellar communication over a distance LL must use wavelengths λ<26.5cm\lambda < 26.5\,cm (to avoid depolarization by the cosmic microwave background), and \emph{enormous} telescopes of effective diameter D>0.78λLD>0.78\sqrt{\lambda L} (to satisfy quantum erasure constraints). For example, for two telescopes of diameter DD on Earth and Proxima Centauri, this implies D>100kmD>100\,km! This is a technological threshold that remains to be crossed in order for reliable one-way quantum communication to become possible, and suggests a fundamental new resolution of the Fermi paradox.

Keywords

Cite

@article{arxiv.2408.02445,
  title  = {On Interstellar Quantum Communication and the Fermi Paradox},
  author = {Latham Boyle},
  journal= {arXiv preprint arXiv:2408.02445},
  year   = {2024}
}

Comments

4+3 pages, 2 figures

R2 v1 2026-06-28T18:04:11.125Z