Quenching the anisotropic Heisenberg chain: Exact solution and generalized gibbs ensemble predictions

B. Wouters; J. De Nardis; M. Brockmann; D. Fioretto; M. Rigol; J. S. Caux

doi:10.1103/PhysRevLett.113.117202

Quenching the anisotropic Heisenberg chain: Exact solution and generalized gibbs ensemble predictions

B. Wouters
, J. De Nardis
, M. Brockmann
, D. Fioretto
, M. Rigol
, J. S. Caux

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

273 Scopus citations

Abstract

We study quenches in integrable spin-1/2 chains in which we evolve the ground state of the antiferromagnetic Ising model with the anisotropic Heisenberg Hamiltonian. For this nontrivially interacting situation, an application of the first-principles-based quench-action method allows us to give an exact description of the postquench steady state in the thermodynamic limit. We show that a generalized Gibbs ensemble, implemented using all known local conserved charges, fails to reproduce the exact quench-action steady state and to correctly predict postquench equilibrium expectation values of physical observables. This is supported by numerical linked-cluster calculations within the diagonal ensemble in the thermodynamic limit.

Original language	English (US)
Article number	117202
Journal	Physical review letters
Volume	113
Issue number	11
DOIs	https://doi.org/10.1103/PhysRevLett.113.117202
State	Published - Sep 12 2014

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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10.1103/PhysRevLett.113.117202

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title = "Quenching the anisotropic Heisenberg chain: Exact solution and generalized gibbs ensemble predictions",

abstract = "We study quenches in integrable spin-1/2 chains in which we evolve the ground state of the antiferromagnetic Ising model with the anisotropic Heisenberg Hamiltonian. For this nontrivially interacting situation, an application of the first-principles-based quench-action method allows us to give an exact description of the postquench steady state in the thermodynamic limit. We show that a generalized Gibbs ensemble, implemented using all known local conserved charges, fails to reproduce the exact quench-action steady state and to correctly predict postquench equilibrium expectation values of physical observables. This is supported by numerical linked-cluster calculations within the diagonal ensemble in the thermodynamic limit.",

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AU - De Nardis, J.

AU - Brockmann, M.

AU - Fioretto, D.

AU - Rigol, M.

AU - Caux, J. S.

PY - 2014/9/12

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N2 - We study quenches in integrable spin-1/2 chains in which we evolve the ground state of the antiferromagnetic Ising model with the anisotropic Heisenberg Hamiltonian. For this nontrivially interacting situation, an application of the first-principles-based quench-action method allows us to give an exact description of the postquench steady state in the thermodynamic limit. We show that a generalized Gibbs ensemble, implemented using all known local conserved charges, fails to reproduce the exact quench-action steady state and to correctly predict postquench equilibrium expectation values of physical observables. This is supported by numerical linked-cluster calculations within the diagonal ensemble in the thermodynamic limit.

AB - We study quenches in integrable spin-1/2 chains in which we evolve the ground state of the antiferromagnetic Ising model with the anisotropic Heisenberg Hamiltonian. For this nontrivially interacting situation, an application of the first-principles-based quench-action method allows us to give an exact description of the postquench steady state in the thermodynamic limit. We show that a generalized Gibbs ensemble, implemented using all known local conserved charges, fails to reproduce the exact quench-action steady state and to correctly predict postquench equilibrium expectation values of physical observables. This is supported by numerical linked-cluster calculations within the diagonal ensemble in the thermodynamic limit.

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Quenching the anisotropic Heisenberg chain: Exact solution and generalized gibbs ensemble predictions

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