Abstract
Gaussian states have played on important role in the physics of continuous-variable quantum systems. They are appealing for the experimental ease with which they can be produced, and for their compact and elegant mathematical description. Nevertheless, many proposed quantum technologies require us to go beyond the realm of Gaussian states and introduce non-Gaussian elements. In this Tutorial, we provide a roadmap for the physics of non-Gaussian quantum states. We introduce the phase-space representations as a framework to describe the different properties of quantum states in continuous-variable systems. We then use this framework in various ways to explore the structure of the state space. We explain how non-Gaussian states can be characterised not only through the negative values of their Wigner function, but also via other properties such as quantum non-Gaussianity and the related stellar rank. For multimode systems, we are naturally confronted with the question of how non-Gaussian properties behave with respect to quantum correlations. To answer this question, we first show how non-Gaussian states can be created by performing measurements on a subset of modes in a Gaussian state. Then, we highlight that these measured modes must be correlated via specific quantum correlations to the remainder of the system to create quantum non-Gaussian or Wigner-negative states. On the other hand, non-Gaussian operations are also shown to enhance or even create quantum correlations. Finally, we will demonstrate that Wigner negativity is a requirement to violate Bell inequalities and to achieve a quantum computational advantage. At the end of the Tutorial, we also provide an overview of several experimental realisations of non-Gaussian quantum states in quantum optics and beyond.
Highlights
Gaussian states have played an important role in the physics of continuous-variable quantum systems
We introduce some key ideas behind quantum non-Gaussianity, the stellar rank, and Wigner negativity as tools to characterize non-Gaussian states
In the remainder of the section, we provide comments on the quantum computational advantage reached with Gaussian Boson sampling
Summary
Gaussian states have a long history in quantum physics, which dates back to Schrödinger’s introduction of the coherent state as a means to study the harmonic oscillator [1]. With the advent of quantum-information theory, the elegant mathematical structure of Gaussian states made them important objects in the study of continuous-variable (CV) quantuminformation theory [7,8,9] In this Tutorial, we focus on bosonic systems, which means that the continuous variables of interest are field quadratures. Gaussian states play a key role in the recent demonstration of a quantum advantage with Gaussian Boson sampling [23] These developments have made the CV quantum optics an important platform for quantum computation [24]. Common schemes, based on the cubic phase gate, turn out to be hard to implement in realistic setups [30] These protocols require highly non-Gaussian states, such as Gottesman-Kitaev-Preskill (GKP) states [31], to encode information.
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