Quantumness and entropic uncertainty in curved space-time

We explore the tripartite entropic uncertainty and genuine tripartite quantumness of Dirac fields in the background of the Garfinkle-Horowitz-Strominger (GHS) dilation space-time. It is interesting to note that Hawking radiation leads to the decay of quantum nonlocality in the physically accessible region while preserving its total coherence. More importantly, it demonstrates an intrinsic trade-off relationship between the coherences of physically accessible and inaccessible regions. Moreover, we examine the effect of Hawking radiation on entropy-based measured uncertainty and find that stronger Hawking radiation causes the uncertainty in physically accessible regions to increase while decreasing the uncertainty in physically inaccessible regions. Therefore, our investigations may be beneficial to a better understanding of the system's quantumness in a curved space-time. Combining relativity theory with quantum information science offers new avenues for comprehending the information paradoxes involving black holes.

Automated summary

In this study, we explore the tripartite entropic uncertainty and genuine tripartite quantumness of Dirac fields in the background of the Garfinkle-Horowitz-Strominger (GHS) dilation space-time. We find that Hawking radiation leads to the decay of quantum nonlocality while preserving total coherence. Moreover, there is an intrinsic trade-off relationship between the coherences of physically accessible and inaccessible regions. Additionally, we examine the effect of Hawking radiation on entropy-based measured uncertainty and observe that stronger Hawking radiation increases uncertainty in physically accessible regions while decreasing it in physically inaccessible regions.