研究目的
To develop a resource theory for continuous-variable systems that quantifies both quantum non-Gaussianity and Wigner negativity as resources, based on operations routinely available within current quantum technologies.
研究成果
The study introduces a general and physically motivated framework for the resource theory of quantum non-Gaussianity and Wigner negativity. It defines a computable monotone, the Wigner logarithmic negativity, and uses it to assess the resource content of experimentally relevant states and the efficiency of resource concentration protocols. The framework is expected to contribute towards the development of subuniversal and universal CV quantum information processing.
研究不足
The study is theoretical and does not involve experimental validation. The framework is limited by the choice of free operations and states, and the absence of a maximally resourceful state in the theory.
1:Experimental Design and Method Selection:
The methodology involves defining free operations (Gaussian protocols) and free states (Gaussian convex hull or states with positive Wigner function). The theoretical framework is based on tools developed to describe quantum systems via their phase-space representation.
2:Sample Selection and Data Sources:
The study focuses on paradigmatic examples of non-Gaussian states such as cubic-phase states, photon-added, photon-subtracted, and cat states.
3:List of Experimental Equipment and Materials:
The study is theoretical and does not specify experimental equipment or materials.
4:Experimental Procedures and Operational Workflow:
The workflow involves defining Gaussian protocols, assessing the resource content of non-Gaussian states, and evaluating the efficiency of resource concentration protocols.
5:Data Analysis Methods:
The analysis involves computing the Wigner logarithmic negativity and comparing it with the non-Gaussianity of pure states.
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