arXiv:2210.10713 Abstract | arXiv Analytics

arXiv:2210.10713 [cond-mat.mes-hall]Abstract References Reviews Resources

How to measure entanglement at finite temperatures?

Published 2022-10-19Version 1

It is desirable to relate entanglement of many-body systems to measurable observables. In systems with a conserved charge, it was recently shown that the number entanglement entropy (NEE) - i.e. the entropy change due to an unselective subsystem charge measurement - is an entanglement monotone. Here we derive finite-temperature equilibrium relations between Renyi moments of the NEE, and multi-point charge correlations. These relations are exemplified in quantum dot systems where the desired charge correlations can be measured via a nearby quantum point contact. In quantum dots recently realizing the multi-channel Kondo effect we show that the NEE has a nontrivial universal temperature dependence which is now accessible using the proposed methods.

Comments: 6 pages, 1 figure, 8 pages of Supplementary material

Categories: cond-mat.mes-hall, cond-mat.str-el

Keywords: finite temperatures, measure entanglement, nearby quantum point contact, charge correlations, nontrivial universal temperature dependence

Related articles: Most relevant | Search more

arXiv:cond-mat/0111415 (Published 2001-11-21)

Transport in quantum wires with impurities at finite temperatures

T. Kleimann, M. Sassetti, B. Kramer

arXiv:0902.3183 [cond-mat.mes-hall] (Published 2009-02-18)

Charge correlations in polaron hopping through molecules

Benjamin B. Schmidt, Matthias H. Hettler, Gerd Schön

arXiv:2205.05658 [cond-mat.mes-hall] (Published 2022-05-11)

Uhlmann holonomy against Lindblad dynamics of topological systems at finite temperatures