Mean field decoupling of single impurity Anderson model through auxiliary Majorana fermions

TY - JOUR

T1 - Mean field decoupling of single impurity Anderson model through auxiliary Majorana fermions

AU - Titvinidze, Irakli

AU - Stobbe, Julian

AU - Rubtosv, Alexey

AU - Rohringer, Georg

PY - 2025/1/9

Y1 - 2025/1/9

N2 - We present a method to study the time evolution of the single impurity Anderson model which exploits a mean field decoupling of the interacting impurity and the non-interacting bath (in form of a chain). This is achieved by the introduction of a pair of auxiliary Majorana fermions between the impurity and the chain. After decoupling, we obtain a self-consistent set of equations for the impurity and chain. First, we study the behavior of the system in equilibrium at zero temperature. We observe a phase transition as a function of the interaction at the impurity and the coupling between the impurity and the chain between the Kondo regime, where the mean field parameters are zero and, hence, we have a well-defined spin at the impurity, to a phase where mean field parameters acquire finite values leading to a screening of the impurity spin by conduction bath electrons. In the latter case, we observe charge and spin fluctuations at the impurity site. Let us note that, while the sharp equilibrium phase transition is a feature of the mean field treatment of the problem it is likely to show itself as a crossover in an exact treatment of the problem. Starting from this equilibrium ground state at zero temperature we quench in the interaction strength at the impurity and/or the hybridization strength between the impurity and the chain and study the time evolution of the system. We find that for quenches to weak to intermediate coupling the system converges to the equilibrium state defined by the final set of parameters after the quench. We analyze the oscillation frequency and as well as the thermalization rate during this quench. A quench to a strong interaction value results in persistent oscillations and a trapping of the system in a non-thermal state. We speculate that these two regimes of different long-time behavior are separated by a dynamical phase transition. We, however, argue that, while our description of the weak to moderate correlated regimes is correct at all time scales, for large final interaction, our approximation is fully valid only at moderate time scale whereas persistent oscillations and related sharp phase transitions are likely artifacts of the mean field treatment of the problem (as in the equilibrium case).

AB - We present a method to study the time evolution of the single impurity Anderson model which exploits a mean field decoupling of the interacting impurity and the non-interacting bath (in form of a chain). This is achieved by the introduction of a pair of auxiliary Majorana fermions between the impurity and the chain. After decoupling, we obtain a self-consistent set of equations for the impurity and chain. First, we study the behavior of the system in equilibrium at zero temperature. We observe a phase transition as a function of the interaction at the impurity and the coupling between the impurity and the chain between the Kondo regime, where the mean field parameters are zero and, hence, we have a well-defined spin at the impurity, to a phase where mean field parameters acquire finite values leading to a screening of the impurity spin by conduction bath electrons. In the latter case, we observe charge and spin fluctuations at the impurity site. Let us note that, while the sharp equilibrium phase transition is a feature of the mean field treatment of the problem it is likely to show itself as a crossover in an exact treatment of the problem. Starting from this equilibrium ground state at zero temperature we quench in the interaction strength at the impurity and/or the hybridization strength between the impurity and the chain and study the time evolution of the system. We find that for quenches to weak to intermediate coupling the system converges to the equilibrium state defined by the final set of parameters after the quench. We analyze the oscillation frequency and as well as the thermalization rate during this quench. A quench to a strong interaction value results in persistent oscillations and a trapping of the system in a non-thermal state. We speculate that these two regimes of different long-time behavior are separated by a dynamical phase transition. We, however, argue that, while our description of the weak to moderate correlated regimes is correct at all time scales, for large final interaction, our approximation is fully valid only at moderate time scale whereas persistent oscillations and related sharp phase transitions are likely artifacts of the mean field treatment of the problem (as in the equilibrium case).

KW - Strongly Correlated Electrons

KW - non-equilibrium quantum systems

KW - Mean Field

UR - https://doi.org/10.1016/j.aop.2024.169904

M3 - Article

SN - 0003-4916

JO - ANNALS OF PHYSICS

JF - ANNALS OF PHYSICS

ER -