Entanglement entropy from charge statistics: Exact relations for noninteracting many-body systems

H. Francis Song; Christian Flindt; Stephan Rachel; Israel Klich; Karyn Le Hur

doi:10.1103/PhysRevB.83.161408

Entanglement entropy from charge statistics: Exact relations for noninteracting many-body systems

H. Francis Song
, Christian Flindt
, Stephan Rachel
, Israel Klich
, Karyn Le Hur

Research output: Contribution to journal › Article › peer-review

Abstract

We present an exact expression for the entanglement entropy generated at a quantum point contact between noninteracting electronic leads in terms of the full counting statistics of charge fluctuations, which we illustrate with examples from both equilibrium and nonequilibrium transport. The formula is also applicable to ground-state entanglement entropy in systems described by noninteracting fermions in any dimension, which in one dimension include the critical spin-1/2 XX and Ising models where conformal field theory predictions for the entanglement entropy are reproduced from the full counting statistics. These results may play an important role in experimental measurements of entanglement entropy in mesoscopic structures and cold atoms in optical lattices.

Original language	English
Article number	161408
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	83
Issue number	16
DOIs	https://doi.org/10.1103/PhysRevB.83.161408
Publication status	Published - 25 Apr 2011
Externally published	Yes

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10.1103/PhysRevB.83.161408

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abstract = "We present an exact expression for the entanglement entropy generated at a quantum point contact between noninteracting electronic leads in terms of the full counting statistics of charge fluctuations, which we illustrate with examples from both equilibrium and nonequilibrium transport. The formula is also applicable to ground-state entanglement entropy in systems described by noninteracting fermions in any dimension, which in one dimension include the critical spin-1/2 XX and Ising models where conformal field theory predictions for the entanglement entropy are reproduced from the full counting statistics. These results may play an important role in experimental measurements of entanglement entropy in mesoscopic structures and cold atoms in optical lattices.",

author = "Song, \{H. Francis\} and Christian Flindt and Stephan Rachel and Israel Klich and \{Le Hur\}, Karyn",

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AU - Klich, Israel

AU - Le Hur, Karyn

PY - 2011/4/25

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N2 - We present an exact expression for the entanglement entropy generated at a quantum point contact between noninteracting electronic leads in terms of the full counting statistics of charge fluctuations, which we illustrate with examples from both equilibrium and nonequilibrium transport. The formula is also applicable to ground-state entanglement entropy in systems described by noninteracting fermions in any dimension, which in one dimension include the critical spin-1/2 XX and Ising models where conformal field theory predictions for the entanglement entropy are reproduced from the full counting statistics. These results may play an important role in experimental measurements of entanglement entropy in mesoscopic structures and cold atoms in optical lattices.

AB - We present an exact expression for the entanglement entropy generated at a quantum point contact between noninteracting electronic leads in terms of the full counting statistics of charge fluctuations, which we illustrate with examples from both equilibrium and nonequilibrium transport. The formula is also applicable to ground-state entanglement entropy in systems described by noninteracting fermions in any dimension, which in one dimension include the critical spin-1/2 XX and Ising models where conformal field theory predictions for the entanglement entropy are reproduced from the full counting statistics. These results may play an important role in experimental measurements of entanglement entropy in mesoscopic structures and cold atoms in optical lattices.

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DO - 10.1103/PhysRevB.83.161408

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JO - Physical Review B - Condensed Matter and Materials Physics

JF - Physical Review B - Condensed Matter and Materials Physics

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Entanglement entropy from charge statistics: Exact relations for noninteracting many-body systems

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