Entanglement, loss, and quantumness: When balanced beam splitters are best
Noah Lupu-Gladstein, Anaelle Hertz, Khabat Heshami, Aaron Z. Goldberg
Abstract
The crux of quantum optics is using beam splitters to generate entanglement, including in pioneering experiments conducted by Hanbury-Brown and Twiss and Hong, Ou, and Mandel. This lies at the heart of what makes boson sampling hard to emulate by classical computers and is a vital component of quantum computation with light. Yet, despite overwhelming positive evidence, the conjecture that beam splitters with equal reflection and transmission probabilities generate the most entanglement for any state interfered with the vacuum has remained unproven for almost two decades [Asbóth et al., Phys. Rev. Lett. \textbf{94}, 173602 (2005)]. We prove this conjecture for ubiquitous entanglement monotones by uncovering monotonicity, convexity, and entropic properties of states undergoing photon loss. Because beam splitters are so fundamental, our results yield numerous corollaries for quantum optics, from inequalities for quasiprobability distributions to proofs of a recent conjecture for the evolution of a measure of quantumness through loss. One can now definitively state: the more balanced a beam splitter, the more entanglement it can generate with the vacuum.