Valence Bond Entanglement Entropy

We introduce for SU(2) symmetric quantum spin systems the notion of Valence Bond Entanglement Entropy as a counting of valence bond spin singlets shared by two subsystems. For a large class of antiferromagnetic systems, this quantity can be calculated via Quantum Monte Carlo simulations directly performed in the valence bond basis. We show that the Valence Bond Entanglement Entropy contains all features of the von Neumann entanglement entropy and offers, among others, the advantage of being computable in all dimensions. In one dimension, predictions for pure conformally invariant and infinite randomness fixed points are recovered. For two-dimensional Heisenberg models, we find a strict area law for a Valence Bond Solid state and an area law with multiplicative logarithmic corrections for the Néel phase.

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Autre [cond-mat.other] Physique Quantique [quant-ph]

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https://hal.science/hal-00169455

Soumis le : mardi 4 septembre 2007-09:41:26

Dernière modification le : mercredi 13 mars 2024-09:40:09

Dates et versions

hal-00169455 , version 1 (04-09-2007)

Identifiants

HAL Id : hal-00169455 , version 1
ARXIV : cond-mat/0703027
DOI : 10.1103/PhysRevLett.99.117204

Citer

Fabien Alet, Sylvain Capponi, Nicolas Laflorencie, Matthieu Mambrini. Valence Bond Entanglement Entropy. Physical Review Letters, 2007, 99 (11), pp.117204. ⟨10.1103/PhysRevLett.99.117204⟩. ⟨hal-00169455⟩

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