Correlation in Catalysts Enables Arbitrary Manipulation of Quantum Coherence

Quantum resource manipulation may include an ancillary state called a catalyst, which aids the transformation while restoring its original form at the end, and characterizing the enhancement enabled by catalysts is essential to reveal the ultimate manipulability of the precious resource quantity of interest. Here, we show that allowing correlation among multiple catalysts can offer arbitrary power in the manipulation of quantum coherence. We prove that any state transformation can be accomplished with an arbitrarily small error by covariant operations with catalysts that may create a correlation within them while keeping their marginal states intact. This presents a new type of embezzlement-like phenomenon, in which the resource embezzlement is attributed to the correlation generated among multiple catalysts. We extend our analysis to general resource theories and provide conditions for feasible transformations assisted by catalysts that involve correlation, putting a severe restriction on other quantum resources for showing this anomalous enhancement, as well as characterizing achievable transformations in relation to their asymptotic state transformations. Our results provide not only a general overview of the power of correlation in catalysts but also a step toward the complete characterization of the resource transformability in quantum thermo-dynamics with correlated catalysts.

Automated summary

This research shows that allowing correlation among multiple catalysts can provide unlimited power in quantum coherence manipulation. Any state transformation can be achieved with minimal error by covariant operations with catalysts that may create correlation within them while keeping their marginal states intact. This phenomenon, called resource embezzlement, attributes the embezzlement of resources to the correlation generated among multiple catalysts. The study also extends the analysis to general resource theories and provides conditions for feasible transformations assisted by catalysts that involve correlation.