Quantum Versus Classical Advantages in Secret Key Distillation (and Their Links to Quantum Entanglement)

TL;DR

This paper compares secret key distillation capabilities between classical and quantum sources, revealing conditions where quantum advantages are significant and linking these advantages to quantum entanglement measures.

Contribution

It establishes the equivalence of classical and quantum key rates for incoherent sources and identifies cases where quantum sources outperform classical ones, with explicit entanglement calculations.

Findings

Classical and quantum key rates are equal for incoherent sources.

Quantum sources can outperform classical sources arbitrarily in key rate.

Entanglement measures can be explicitly computed for certain quantum states.

Abstract

We consider the extraction of shared secret key from correlations that are generated by either a classical or quantum source. In the classical setting, two honest parties (Alice and Bob) use public discussion and local randomness to distill secret key from some distribution $p_{XYZ}$ that is shared with an unwanted eavesdropper (Eve). In the quantum settings, the correlations $p_{XYZ}$ are delivered to the parties as either an \textit{incoherent} mixture of orthogonal quantum states or as \textit{coherent} superposition of such states; in both cases, Alice and Bob use public discussion and local quantum operations to distill secret key. While the power of quantum mechanics increases Alice and Bob's ability to generate shared randomness, it also equips Eve with a greater arsenal of eavesdropping attacks. Therefore, it is not obvious who gains the greatest advantage for distilling secret key when replacing a classical source with a quantum one. In this paper we first demonstrate that the classical key rate is equivalent to the quantum key rate when the correlations are generated incoherently in the quantum setting. For coherent sources, we next show that the rates are incomparable, and in fact, their difference can be arbitrarily large in either direction. However, we identify a large class of non-trivial distributions $p_{XYZ}$ that possess the following properties: (i) Eve's advantage is always greater in the quantum source than in its classical counterpart, and (ii) for the quantum entanglement shared between Alice and Bob in the coherent source, the so-called entanglement cost/squashed entanglement/relative entropy of entanglement can all be computed. With property (ii), we thus present a rare instance in which the various entropic entanglement measures of a quantum state can be explicitly calculated.