Perturbation study of nonequilibrium quasiparticle spectra in an infinite-dimensional Hubbard lattice

Heary, Ryan; Han, Jong E.

doi:10.1103/physrevb.80.035102

Cited by 6 publications

(7 citation statements)

References 27 publications

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“…From a technical point of view, this requires to consider spatially inhomogeneous systems and in layered heterostructures. The difficulties in solving an inhomogeneous system out of equilibrium suggested to address the problem starting from the stationary state [390,[572][573][574][575].…”

Section: Electric Fields In Correlated Heterostructuresmentioning

confidence: 99%

Ultrafast optical spectroscopy of strongly correlated materials and high-temperature superconductors: a non-equilibrium approach

Giannetti,

Capone,

Fausti

et al. 2016

Preprint

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Contents 7.3. Correlated systems in electric fields 7.3.1. Correlated electrons in a d.c. electric field 7.3.2. Dissipation and approach to steady states 7.3.3. Periodic a.c. electric fields 7.3.4. Electric fields in correlated heterostructures 7.3.5. Electric-field driven Mott transitions and resistive switching 7.3.6. Light-induced excitation and photodoping 7.4. Quantum quenches and dynamical phase transitions in simple models 7.5. Melting of antiferromagnetism and broken-symmetry phases 7.6. Non-equilibrium dynamics beyond the single-band Hubbard model 7.7. Electron-phonon interaction beyond the two-temperature model 8. Experimental perspectives 9. Acknowledgements 10. References

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Section: Electric Fields In Correlated Heterostructuresmentioning

confidence: 99%

Ultrafast optical spectroscopy of strongly correlated materials and high-temperature superconductors: a non-equilibrium approach

Giannetti,

Capone,

Fausti

et al. 2016

Preprint

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“…The weak-coupling perturbation theory has been used for a long time as an impurity solver in equilibrium DMFT calculations (Georges and Kotliar, 1992;Zhang, Rozenberg, and Kotliar, 1993;Freericks, 1994;Freericks and Jarrell, 1994;Georges et al, 1996), and in the nonequilibrium DMFT context, it has enabled a range of studies of the Hubbard model (Schmidt and Monien, 2002;Heary and Han, 2009;Eckstein and Werner, 2011a;Amaricci et al, 2012;Aron, Kotliar, and Weber, 2012;Tsuji et al, 2012;Tsuji, Eckstein, and Werner, 2013) and of the FalicovKimball model (Turkowski and Freericks, 2007a).…”

Section: Weak-coupling Perturbation Theorymentioning

confidence: 99%

Nonequilibrium dynamical mean-field theory and its applications

et al. 2014

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The study of nonequilibrium phenomena in correlated lattice systems has developed into one of the most active and exciting branches of condensed matter physics. This research field provides rich new insights that could not be obtained from the study of equilibrium situations, and the theoretical understanding of the physics often requires the development of new concepts and methods. On the experimental side, ultrafast pump-probe spectroscopies enable studies of excitation and relaxation phenomena in correlated electron systems, while ultracold atoms in optical lattices provide a new way to control and measure the time evolution of interacting lattice systems with a vastly different characteristic time scale compared to electron systems. A theoretical description of these phenomena is challenging because, first, the quantum-mechanical time evolution of many-body systems out of equilibrium must be computed and second, strong-correlation effects which can be of a nonperturbative nature must be addressed. This review discusses the nonequilibrium extension of the dynamical mean field theory (DMFT), which treats quantum fluctuations in the time domain and works directly in the thermodynamic limit. The method reduces the complexity of the calculation via a mapping to a selfconsistent impurity problem, which becomes exact in infinite dimensions. Particular emphasis is placed on a detailed derivation of the formalism, and on a discussion of numerical techniques, which enable solutions of the effective nonequilibrium DMFT impurity problem. Insights gained into the properties of the infinite-dimensional Hubbard model under strong nonequilibrium conditions are summarized. These examples illustrate the current ability of the theoretical framework to reproduce and understand fundamental nonequilibrium phenomena, such as the dielectric breakdown of Mott insulators, photodoping, and collapse-and-revival oscillations in quenched systems. Furthermore, remarkable novel phenomena have been predicted by the nonequilibrium DMFT simulations of correlated lattice systems, including dynamical phase transitions and field-induced repulsion-to-attraction conversions.

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“…Perturbation theory for nonequilibrium impurity problems (Fujii and Ueda, 2003;Hershfield et al, 1991Hershfield et al, , 1992) is a straightforward generalization of the equilibrium perturbation theory formulated on the Matsubara branch (Abrikosov et al, 1975;Mahan, 2000;Yosida andYamada, 1970, 1975). The weak-coupling perturbation theory has been used for a long time as an impurity solver in equilibrium DMFT calculations (Freericks, 1994;Freericks and Jarrell, 1994;Georges and Kotliar, 1992;Georges et al, 1996;Zhang et al, 1993), and in the nonequilibrium DMFT context, it has enabled a range of studies of the Hubbard model (Amaricci et al, 2012;Aron et al, 2012;Eckstein et al, 2010a;Eckstein and Werner, 2011a;Heary and Han, 2009;Schmidt and Monien, 2002;Tsuji et al, 2013bTsuji et al, , 2012Tsuji and Werner, 2013) and of the Falicov-Kimball model (Turkowski and Freericks, 2007a).…”

Section: Weak-coupling Perturbation Theorymentioning

confidence: 99%

Nonequilibrium dynamical mean-field theory and its applications

Aoki,

Tsuji,

Eckstein

et al. 2013

Preprint

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The study of nonequilibrium phenomena in correlated lattice systems has developed into one of the most active and exciting branches of condensed matter physics. This research field provides rich new insights that could not be obtained from the study of equilibrium situations, and the theoretical understanding of the physics often requires the development of new concepts and methods. On the experimental side, ultrafast pump-probe spectroscopies enable studies of excitation and relaxation phenomena in correlated electron systems, while ultracold atoms in optical lattices provide a new way to control and measure the time evolution of interacting lattice systems with a vastly different characteristic time scale compared to electron systems. A theoretical description of these phenomena is challenging because, first, the quantum-mechanical time evolution of many-body systems out of equilibrium must be computed and second, strong-correlation effects which can be of nonperturbative nature must be addressed. This review discusses the nonequilibrium extension of the dynamical mean field theory (DMFT), which treats quantum fluctuations in the time domain and works directly in the thermodynamic limit. The method reduces the complexity of the calculation via a mapping to a self-consistent impurity problem, which becomes exact in infinite dimensions. Particular emphasis is placed on a detailed derivation of the formalism, and on a discussion of numerical techniques, which enable solutions of the effective nonequilibrium DMFT impurity problem. Insights gained into the properties of the infinite-dimensional Hubbard model under strong nonequilibrium conditions are summarized. These examples illustrate the current ability of the theoretical framework to reproduce and understand fundamental nonequilibrium phenomena, such as the dielectric breakdown of Mott insulators, photodoping, and collapse-and-revival oscillations in quenched systems. Furthermore, remarkable novel phenomena have been predicted by the nonequilibrium DMFT simulations of correlated lattice systems, including dynamical phase transitions and field-induced repulsion-to-attraction conversions.

show abstract

Perturbation study of nonequilibrium quasiparticle spectra in an infinite-dimensional Hubbard lattice

Cited by 6 publications

References 27 publications

Ultrafast optical spectroscopy of strongly correlated materials and high-temperature superconductors: a non-equilibrium approach

Ultrafast optical spectroscopy of strongly correlated materials and high-temperature superconductors: a non-equilibrium approach

Nonequilibrium dynamical mean-field theory and its applications

Nonequilibrium dynamical mean-field theory and its applications

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