A generalized multi-polaron expansion for the spin-boson model: Environmental entanglement and the biased two-state system

TL;DR

This paper introduces a variational multi-polaron expansion for the spin-boson model, capturing environmental entanglement and system coherence, with results validated against NRG and Bethe Ansatz solutions, applicable to complex quantum dissipative systems.

Contribution

A systematic variational coherent state expansion for the spin-boson model that effectively captures environmental entanglement and system properties, improving upon previous methods.

Findings

Rapid convergence of the multi-polaron expansion.

Significant environmental entanglement at strong dissipation.

Accurate results consistent with NRG and Bethe Ansatz.

Abstract

We develop a systematic variational coherent state expansion for the many-body ground state of the spin-boson model, in which a quantum two-level system is coupled to a continuum of harmonic oscillators. Energetic constraints at the heart of this technique are rationalized in terms of polarons (displacements of the bath states in agreement with classical expectations) and antipolarons (counter-displacements due to quantum tunneling effects). We present a comprehensive study of the ground state two-level system population and coherence as a function of tunneling amplitude, dissipation strength, and bias (akin to asymmetry of the double well potential defining the two-state system). The entanglement among the different environmental modes is investigated by looking at spectroscopic signatures of the bipartite entanglement entropy between a given environmental mode and all the other modes. We observe a drastic change in behavior of this entropy for increasing dissipation, indicative of the entangled nature of the environmental states. In addition, the entropy spreads over a large energy range at strong dissipation, a testimony to the wide entanglement window characterizing the underlying Kondo state. Finally, comparisons to accurate numerical renormalization group calculations and to the exact Bethe Ansatz solution of the model demonstrate the rapid convergence of our variationally-optimized multi-polaron expansion, suggesting that it should also be a useful tool for dissipative models of greater complexity, as relevant for numerous systems of interest in quantum physics and chemistry.