Add to ORKGThe entanglement at finite temperatures is analyzed by using thermal models for colored quarks making tip the hadron physical states. We have found that these quantum correlations entirely vanish at T-c >= m(q)/ln(1.5). For temperatures larger than T-c the correlations are classical. We have also worked out the entanglement for the transverse Ising spin chain. In dependence on both temperature T and transverse field A we can identify a certain region, where the quantum effects are likely to dominate the system. We suggest the mutual information as a quantitative measure for the correlations in the ground state.</p
We investigate the fundamental limitations imposed by thermodynamics for creating correlations. Cons...
By using the method of exact diagonalization, we investigate the quantum correlation measured by qu...
At finite temperatures, the quantum critical region (QCR) emerges as a consequence of the interplay ...
The entanglement at finite temperatures is analyzed by using thermal models for colored quarks makin...
The entanglement at finite temperatures is analyzed by using thermal models for colored quarks makin...
The entanglement at finite temperatures is analyzed by using thermal models for colored quarks makin...
The entanglement at finite temperatures is analyzed by using thermal models for colored quarks makin...
The entanglement at finite temperatures is analyzed by using thermal models for colored quarks makin...
The entanglement at finite temperatures are analyzed by using thermal models for colored quarks maki...
In this work we analyze the quantum entropy at finite temperatures using models for colored quarks m...
We study thermal entanglement in some low-dimensional Heisenberg models. It is found that in each mo...
The investigation of quantum and classical correlations has mostly concentrated on two-qub...
We study the finite-temperature behavior of the Lipkin-Meshkov-Glick model with a focus on correlati...
We study the finite-temperature behavior of the Lipkin-Meshkov-Glick model with a focus on correlati...
The relationship between the mean-field approximations in various interacting models of statistical ...
We investigate the fundamental limitations imposed by thermodynamics for creating correlations. Cons...
By using the method of exact diagonalization, we investigate the quantum correlation measured by qu...
At finite temperatures, the quantum critical region (QCR) emerges as a consequence of the interplay ...
The entanglement at finite temperatures is analyzed by using thermal models for colored quarks makin...
The entanglement at finite temperatures is analyzed by using thermal models for colored quarks makin...
The entanglement at finite temperatures is analyzed by using thermal models for colored quarks makin...
The entanglement at finite temperatures is analyzed by using thermal models for colored quarks makin...
The entanglement at finite temperatures is analyzed by using thermal models for colored quarks makin...
The entanglement at finite temperatures are analyzed by using thermal models for colored quarks maki...
In this work we analyze the quantum entropy at finite temperatures using models for colored quarks m...
We study thermal entanglement in some low-dimensional Heisenberg models. It is found that in each mo...
The investigation of quantum and classical correlations has mostly concentrated on two-qub...
We study the finite-temperature behavior of the Lipkin-Meshkov-Glick model with a focus on correlati...
We study the finite-temperature behavior of the Lipkin-Meshkov-Glick model with a focus on correlati...
The relationship between the mean-field approximations in various interacting models of statistical ...
We investigate the fundamental limitations imposed by thermodynamics for creating correlations. Cons...
By using the method of exact diagonalization, we investigate the quantum correlation measured by qu...
At finite temperatures, the quantum critical region (QCR) emerges as a consequence of the interplay ...