English

Coherifying quantum channels

Quantum Physics 2018-05-16 v2

Abstract

Is it always possible to explain random stochastic transitions between states of a finite-dimensional system as arising from the deterministic quantum evolution of the system? If not, then what is the minimal amount of randomness required by quantum theory to explain a given stochastic process? Here, we address this problem by studying possible coherifications of a quantum channel Φ\Phi, i.e., we look for channels ΦC\Phi^{\mathcal{C}} that induce the same classical transitions TT, but are "more coherent". To quantify the coherence of a channel Φ\Phi we measure the coherence of the corresponding Jamio{\l}kowski state JΦJ_{\Phi}. We show that the classical transition matrix TT can be coherified to reversible unitary dynamics if and only if TT is unistochastic. Otherwise the Jamio{\l}kowski state JΦCJ_\Phi^{\mathcal{C}} of the optimally coherified channel is mixed, and the dynamics must necessarily be irreversible. To assess the extent to which an optimal process ΦC\Phi^{\mathcal{C}} is indeterministic we find explicit bounds on the entropy and purity of JΦCJ_\Phi^{\mathcal{C}}, and relate the latter to the unitarity of ΦC\Phi^{\mathcal{C}}. We also find optimal coherifications for several classes of channels, including all one-qubit channels. Finally, we provide a non-optimal coherification procedure that works for an arbitrary channel Φ\Phi and reduces its rank (the minimal number of required Kraus operators) from d2d^2 to dd.

Keywords

Cite

@article{arxiv.1710.04228,
  title  = {Coherifying quantum channels},
  author = {Kamil Korzekwa and Stanisław Czachórski and Zbigniew Puchała and Karol Życzkowski},
  journal= {arXiv preprint arXiv:1710.04228},
  year   = {2018}
}

Comments

20 pages, 8 figures. Published version

R2 v1 2026-06-22T22:10:39.676Z