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Quantum phase transitions in the spin-boson model: Monte Carlo method versus variational approach à la Feynman

G. De Filippis, A. de Candia, Loris Maria Cangemi, Maura Sassetti, Rosario Fazio, V. Cataudella

2020Physical review. B./Physical review. B23 citationsDOIOpen Access PDF

Abstract

The effectiveness of the variational approach \`a la Feynman is proved in the spin-boson model, i.e., the simplest realization of the Caldeira-Leggett model able to reveal the quantum phase transition from delocalized to localized states and the quantum dissipation and decoherence effects induced by a heat bath. After exactly eliminating the bath degrees of freedom, we propose a trial, nonlocal in time, interaction between the spin and itself simulating the coupling of the two-level system with the bosonic bath. It stems from a Hamiltonian where the spin is linearly coupled to a finite number of harmonic oscillators whose frequencies and coupling strengths are variationally determined. We show that a very limited number of these fictitious modes is enough to get a remarkable agreement, up to very low temperatures, with the data obtained by using an approximation-free Monte Carlo approach, predicting (1) in the Ohmic regime, a Berezinski-Thouless-Kosterlitz quantum phase transition exhibiting the typical universal jump at the critical value; and (2) in the sub-Ohmic regime ($s\ensuremath{\le}0.5$), mean-field quantum phase transitions, with logarithmic corrections for $s=0.5$.

Topics & Concepts

PhysicsHamiltonian (control theory)Quantum mechanicsQuantum Monte CarloQuantum decoherenceQuantum phase transitionFeynman diagramBosonQuantumPhase transitionQuantum electrodynamicsMonte Carlo methodMathematicsStatisticsMathematical optimizationSpectroscopy and Quantum Chemical StudiesQuantum many-body systemsTheoretical and Computational Physics
Quantum phase transitions in the spin-boson model: Monte Carlo method versus variational approach à la Feynman | Litcius