Exact diagonalization study of the Hubbard-parametrized four-spin ring exchange model on a square lattice

We have used exact numerical diagonalization to study the excitation spectrum and the dynamic spin correlations in the \(s=1/2\) next-next-nearest neighbor Heisenberg antiferromagnet on the square lattice, with additional 4-spin ring exchange from higher order terms in the Hubbard expansion. We have...

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Bibliographic Details
Published in:arXiv.org 2018-12
Main Authors: Larsen, C B, Rømer, A T, Janas, S, Treue, F, Mønsted, B, Shaik, N E, Rønnow, H M, Lefmann, K
Format: Article
Language:English
Subjects:
Antiferromagnetism
Critical point
Exchanging
Excitation spectra
Mathematical models
Parameterization
Parameters
Phase transitions
Quantum phenomena
Spin dynamics
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Summary:We have used exact numerical diagonalization to study the excitation spectrum and the dynamic spin correlations in the \(s=1/2\) next-next-nearest neighbor Heisenberg antiferromagnet on the square lattice, with additional 4-spin ring exchange from higher order terms in the Hubbard expansion. We have varied the ratio between Hubbard model parameters, \(t/U\), to obtain different relative strengths of the exchange parameters, while keeping electrons localized. The Hubbard model parameters have been parametrized via an effective ring exchange coupling, \(J_r\), which have been varied between 0\(J\) and 1.5\(J\). We find that ring exchange induces a quantum phase transition from the \((\pi, \pi)\) ordered Neèl state to a \((\pi/2, \pi/2)\) ordered state. This quantum critical point is reduced by quantum fluctuations from its mean field value of \(J_r/J = 2\) to a value of \(\sim 1.1\). At the quantum critical point, the dynamical correlation function shows a pseudo-continuum at \(q\)-values between the two competing ordering vectors.
ISSN:2331-8422
DOI:10.48550/arxiv.1812.04277