Quantifying quantum coherence via nonreal Kirkwood-Dirac quasiprobability

TL;DR

This paper introduces a method to quantify quantum coherence using the imaginary part of Kirkwood-Dirac quasiprobability, linking it to quantum uncertainty and providing practical measurement strategies.

Contribution

It proposes a novel coherence measure based on KD quasiprobability, connecting it to quantum uncertainty and offering measurement and interpretation frameworks.

Findings

The $l_1$-norm of the imaginary part of KD quasiprobability quantifies quantum coherence.

The measure is bounded by quantum uncertainty and equals coherence for single qubits.

Measurement schemes for KD coherence are discussed with statistical and hybrid quantum-classical approaches.

Abstract

Kirkwood-Dirac (KD) quasiprobability is a quantum analog of phase space probability of classical statistical mechanics, allowing negative or/and nonreal values. It gives an informationally complete representation of a quantum state. Recent works have revealed the important roles played by the KD quasiprobability in the broad fields of quantum science and quantum technology. In the present work, we use the KD quasiprobability to access the quantum coherence in a quantum state. We show that the $l_1$-norm of the imaginary part of the KD quasiprobability over an incoherent reference basis and a second basis, maximized over all possible choices of the latter, can be used to quantify quantum coherence, satisfying certain desirable properties. It is upper bounded by the quantum uncertainty, i.e., the quantum standard deviation, of the incoherent basis in the state. It gives a lower bound to the $l_1$-norm quantum coherence, and for a single qubit, they are identical. We discuss the measurement of the KD coherence based on the measurement of the KD quasiprobability and an optimization procedure in hybrid quantum-classical schemes, and suggest statistical interpretations. We also discuss its relevance in the physics of linear response regime.