The Janus State: A Universal Lower Bound for Second-Order Coherence
Abstract
A single-mode squeezed vacuum is a foundational quantum state that, despite its nonclassical nature, exhibits classical-like, super-Poissonian photon statistics. This feature motivates a ``quantum-of-quantum'' inquiry: can the superposition of two such states generate the opposite behavior -- strongly sub-Poissonian light? We demonstrate that the ``Janus state,'' a coherent superposition of two squeezed vacua with opposing orientations, achieves precisely this. Our exact analytic solution reveals a universal lower bound on second-order coherence, showing that cannot be driven below 1/2. The mechanism is tuned interference that suppresses two-photon events. Beyond this asymptotic bound, we identify a practical minimum of at moderate squeezing, defining an accessible ``sweet spot.'' While requiring a minimal non-Gaussian element for its creation, the Janus state establishes a definitive performance limit for engineering sub-Poissonian photon statistics from Gaussian resources, with a clear path toward quantum applications.
Cite
@article{arxiv.2506.06397,
title = {The Janus State: A Universal Lower Bound for Second-Order Coherence},
author = {Arash Azizi},
journal= {arXiv preprint arXiv:2506.06397},
year = {2026}
}
Comments
4 pages, 7 figures, and Supplementary. V2: Introducing Janus state. V3: Finding the new minimum, adding a fig. V4: Published version with SI