Entanglement entropy, single-particle occupation probabilities, and short-range correlations
| Autor: | Bulgac, Aurel |
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| Rok vydání: | 2022 |
| Předmět: | |
| Zdroj: | Physical Review C 107, L061602 (2023) |
| Druh dokumentu: | Working Paper |
| DOI: | 10.1103/PhysRevC.107.L061602 |
| Popis: | For quantum many-body systems with short-range correlations (SRCs), the intimate relationship between their magnitude, the behavior of the single-particle occupation probabilities at momenta larger than the Fermi momentum, and the entanglement entropy is a new qualitative aspect not studied and exploited yet. A large body of recent condensed matter studies indicate that the time evolution of the entanglement entropy describes the non-equilibrium dynamics of isolated and strongly interacting many-body systems, in a manner similar to the Boltzmann entropy, which is strictly defined for dilute and weakly interacting many-body systems. Both theoretical and experimental studies in nuclei and cold atomic gases have shown that the fermion momentum distribution has a generic behavior $n(k)=C/k^4$ at momenta larger than the Fermi momentum, due to the presence of SRCs, with approximately 20\% of the particles having momenta larger than the Fermi momentum. The presence of the long momentum tails in the presence of SRCs changes the textbook relation between the single-particle kinetic energy and occupation probabilities, $n_\text{mf}(k) = {1}/\{ 1+\exp\beta[\epsilon(k)-\mu]\}$ for momenta very different form the Fermi momentum, particularly for dynamics processes. SRCs induced high-momentum tails of the single-particle occupation probabilities increase the entanglement entropy of fermionic systems, which in its turn affects the dynamics of many nuclear reactions, such as heavy-ion collisions and nuclear fission. Comment: 8 pages, 5 figures, updated figures, tex, material and references in agreement with published version |
| Databáze: | arXiv |
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