Global quantum discord in the Lipkin-Meshkov-Glick model at zero and finite temperatures

We study the global quantum discord (GQD) in the Lipkin-Meshkov-Glick (LMG) model at zero and finite temperatures, in which all spins are mutually interacted and introduced in an external magnetic field (denoted by h). We confirm that the high coordinate number is one of the most distinguishing features of the LMG model, which directly results in the nontrivial behaviors of quantum correlations. We compare the GQD with other quantum correlations measures (such as concurrence, quantum discord, and global entanglement) and find the remarkable difference between them. For instance, we find that GQD spreads in the entire system and captures more information on quantum correlations when comparing with concurrence and quantum (pairwise) discord. We discover that GQD can characterize multipartite correlations in the both broken phase (h < 1) and the symmetric phase (h >= 1), while global entanglement and its generalized fail. Moreover, we show that the ground-state GQD can identify second-order quantum phase transitions of the LMG model in the thermodynamic limit. By making the scaling behavior of the GQD in the LMG model analysis, we show that GQD (denoted by G) scales asG similar to k . N + c with k > 0 in the anisotropic cases for any fixed magnetic field. We further show that GQD behaves as G vertical bar(sn) similar to k (.) 1/N + c with k < 0 in the isotropic cases for any Dicke state vertical bar(sn). Herein k and c are the fitting parameters. We also find that the thermal stability of the GQD at low temperatures depends on the energy gap. We further reveal that the extraordinary behaviors of the thermal-state GQD in the isotropic LMG model are explained by the contribution theory of the energy levels.

Automated summary

This study investigates the global quantum discord (GQD) in the Lipkin-Meshkov-Glick (LMG) model at zero and finite temperatures, comparing it with other quantum correlations measures. It is found that GQD spreads throughout the entire system and captures more information on quantum correlations than concurrence and quantum discord. Additionally, the ground-state GQD is able to identify second-order quantum phase transitions of the LMG model in the thermodynamic limit.