Quantum Oscillons are Long-Lived
Abstract
As the longest lived transient, oscillons play a critical role in classical field theory simulations of many phenomena. However, beyond the classical approximation, it is well-known that quantum corrections open decay channels through which oscillons radiate rapidly. Therefore it is believed that in the real world, oscillons are too short-lived to be phenomenologically relevant. We observe that previous calculations of the radiated power assume that the oscillon is in a coherent state. We show that a squeezed coherent state, on the other hand, would emit no radiation at leading order in the coupling. This leads us to the conclusion that the instantaneous radiation calculated in the literature corresponds not to the oscillon's decay, but rather to its relaxation from a coherent state to a lower-energy, squeezed coherent state, which then radiates much more slowly. As a result, the lifetime of the quantum oscillon is enhanced by an inverse power of the coupling.
Cite
@article{arxiv.2512.17193,
title = {Quantum Oscillons are Long-Lived},
author = {Jarah Evslin and Katarzyna Slawińska and Tomasz Romańczukiewicz and Andrzej Wereszczyński},
journal= {arXiv preprint arXiv:2512.17193},
year = {2026}
}
Comments
9 pages, 1 PDF figure, v2 +discussion of dynamic relaxation to squeezed state