Litcius/Paper detail

Quantum states as observables: Their variance and nonclassicality

Yue Zhang, Shunlong Luo

2020Physical review. A/Physical review, A25 citationsDOI

Abstract

Two basic ingredients in the quantum formalism are the concepts of states and observables, and apart from the average value (which includes the Born probability as a paramountly important case), the variance is the most fundamental and prominent quantity arising from the coupling of a state and an observable. Given the simplicity and ubiquity of the variance, it seems surprising that we can still exploit the variance to gain conceptually different insight into the quantum substratum. The purpose of the present work is to advocate the following idea: By inputting a general quantum state as the observable in the variance and incorporating a resolution of identity induced by coherent states, we obtain a mathematically simple and physically intuitive method for quantifying nonclassicality. We reveal its fundamental properties and highlight its connection with phase-space quantification of nonclassicality. The idea further suggests a whole family of appealing quantifiers of nonclassicality involving deep mathematical subtlety and an intriguing conjecture with physical significance. Some prototypical examples are worked out to illustrate the concept. This approach of regarding states as observables presents an opportunity for investigating quantum features from an alternative perspective of uncertainty.

Topics & Concepts

ObservableVariance (accounting)Statistical physicsQuantumComputer scienceQuantum stateFormalism (music)Theoretical physicsQuantum entanglementMathematicsQuantum mechanicsPhysicsVisual artsMusicalAccountingArtBusinessQuantum Information and CryptographyQuantum Mechanics and ApplicationsAdvanced Thermodynamics and Statistical Mechanics