Abstract

Negativity of the Wigner function is arguably one of the most striking non-classical features of quantum states. Beyond its fundamental relevance, it is also a necessary resource for quantum speedup with continuous variables. As quantum technologies emerge, the need to identify and characterize the resources which provide an advantage over existing classical technologies becomes more pressing. Here we derive witnesses for Wigner negativity of single mode and multimode quantum states, based on fidelities with Fock states, which can be reliably measured using standard detection setups. They possess a threshold expectation value indicating whether the measured state has a negative Wigner function. Moreover, the amount of violation provides an operational quantification of Wigner negativity. We phrase the problem of finding the threshold values for our witnesses as an infinite-dimensional linear optimisation. By relaxing and restricting the corresponding linear programs, we derive two hierarchies of semidefinite programs, which provide numerical sequences of increasingly tighter upper and lower bounds for the threshold values. We further show that both sequences converge to the threshold value. Moreover, our witnesses form a complete family – each Wigner negative state is detected by at least one witness – thus providing a reliable method for experimentally witnessing Wigner negativity of quantum states from few measurements. From a foundational perspective, our findings provide insights on the set of positive Wigner functions which still lacks a proper characterisation.

Highlights

  • Quantum information with continuous variables [1]—where information is encoded in continuous degrees of freedom of quantum systems—is one of the promising directions for the future of quantum technologies

  • Given that all Fock states—with the exception of the (Gaussian) vacuum state |0 —have a negative Wigner function, we introduce a broad family of Wigner negativity witnesses for single-mode continuous-variable quantum states based on fidelities with Fock states

  • Characterising quantum properties of physical systems is an important step in the development of quantum technologies and negativity of the Wigner function, a necessary resource for any quantum computational speedup, is no exception

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Summary

Introduction

Quantum information with continuous variables [1]—where information is encoded in continuous degrees of freedom of quantum systems—is one of the promising directions for the future of quantum technologies. To handily manipulate states in those infinite spaces, mathematical tools initially inspired by physics have been developed such as phasespace formalism [4] In this framework, quantum states are represented by a quasi-probability distribution over phase space, like the Wigner function [5]. These representations provide a geometric intuition of quantum states [6]: quantum states are separated into two categories, Gaussian and non-Gaussian, depending on whether their Wigner function is a Gaussian function or not.

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