# Dynamical Correlation Functions of the Quadratic Coupling Spin-Boson   Model

**Authors:** Da-Chuan Zheng, Ning-Hua Tong

arXiv: 1703.00618 · 2018-11-19

## TL;DR

This paper investigates the dynamical correlation functions of the quadratic coupling spin-boson model using numerical renormalization group methods, revealing power-law behaviors, critical exponents, and dephasing effects near phase transitions.

## Contribution

It provides a detailed analysis of dynamical correlation functions and critical exponents in the quadratic coupling spin-boson model, which was not previously characterized.

## Key findings

- Power-law frequency dependence of correlation functions in weak coupling.
- Critical exponents at the quantum phase transition point.
- Enhanced dephasing and line shape changes near the spin flip point.

## Abstract

The spin-boson model with quadratic coupling is studied using the bosonic numerical renormalization group method. We focus on the dynamical auto-correlation functions $C_{O}(\omega)$, with the operator $\hat{O}$ taken as $\hat{\sigma}_x$, $\hat{\sigma}_z$, and $\hat{X}$, respectively. In the weak-coupling regime $\alpha < \alpha_c$, these functions show power law $\omega$-dependence in the small frequency limit, with the powers $1+2s$, $1+2s$, and $s$, respectively. At the critical point $\alpha = \alpha_c$ of the boson-unstable quantum phase transition, the critical exponents $y_{O}$ of these correlation functions are obtained as $y_{\sigma_x} = y_{\sigma_z} = 1-2s$ and $y_{X}=-s$, respectively. Here $s$ is the bath index and $X$ is the boson displacement operator. Close to the spin flip point, the high frequency peak of $C_{\sigma_{x}}(\omega)$ is broadened significantly and the line shape changes qualitatively, showing enhanced dephasing at the spin flip point.

## Full text

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## Figures

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## References

49 references — full list in the complete paper: https://tomesphere.com/paper/1703.00618/full.md

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Source: https://tomesphere.com/paper/1703.00618