Computation of ESR spectra from the time evolution of the magnetization: comparison of autocorrelation and Wiener-Khinchin-relation based methods

TL;DR

This paper compares autocorrelation and Wiener-Khinchin-based methods for computing ESR spectra in quantum spin systems, demonstrating both methods' accuracy and analyzing statistical properties and finite-size effects.

Contribution

It introduces a novel Wiener-Khinchin-like method for quantum ESR spectra and compares it with autocorrelation-based approaches, highlighting their accuracy and statistical characteristics.

Findings

Both methods produce correct ESR spectra compared to exact diagonalization.

Finite observation time effects diminish with increasing system size.

The double peak structure in spectra is robust for the XXZ Heisenberg chain.

Abstract

The calculation of finite temperature ESR spectra for concrete specified crystal configurations is a very important issue in the study of quantum spin systems. Although direct evaluation of the Kubo formula by means of numerical diagonalization yields exact results, memory and CPU-time restrictions limit the applicability of this approach to small system sizes. Methods based on the time evolution of a single pure quantum state can be used to study larger systems. One such method exploits the property that the expectation value of the autocorrelation function obtained for a few samples of so-called thermal typical states yields a good estimate of the thermal equilibrium value. In this paper, we propose a new method based on a Wiener-Khinchin-like theorem for quantum system. By comparison with exact diagonalization results, it is shown that both methods yield correct results. As the Wiener-Khinchin-based method involves sampling over thermal typical states, we study the statistical properties of the sampling distribution. Effects due to finite observation time are investigated and found to be different for the two methods but it is also found that for both methods, the effects vanish as the system size increases. We present ESR spectra of the one-dimensional XXZ Heisenberg chain of up to 26 spins show that double peak structure due to the anisotropy is a robust feature of these spectra.