Fidelity spectrum and phase transitions of quantum systems
arXiv:1107.5931 · doi:10.1103/PhysRevA.84.062318
Abstract
Quantum fidelity between two density matrices, $F(Ï_1,Ï_2)$ is usually defined as the trace of the operator ${\cal F}=\sqrt{\sqrt{Ï_1} Ï_2 \sqrt{Ï_1}}$. We study the logarithmic spectrum of this operator, which we denote by {\it fidelity spectrum}, in the cases of the $XX$ spin chain in a magnetic field, a magnetic impurity inserted in a conventional superconductor and a bulk superconductor at finite temperature. When the density matrices are equal, $Ï_1=Ï_2$, the fidelity spectrum reduces to the entanglement spectrum. We find that the fidelity spectrum can be a useful tool in giving a detailed characterization of different phases of many-body quantum systems.
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