Magnetic Field Response of Dipolar-Octupolar Quantum Spin Ice

TL;DR

This paper uses gauge mean-field theory to analyze the magnetic field response of dipolar-octupolar quantum spin ice, providing phase diagrams and spin structure factor evolutions to guide experimental verification of its quantum spin liquid state.

Contribution

It offers the first comprehensive theoretical study of magnetic field effects on dipolar-octupolar quantum spin ice beyond perturbative approaches.

Findings

Constructed phase diagrams for different magnetic field directions.

Predicted evolution of spin structure factors under magnetic fields.

Provided theoretical benchmarks for experimental confirmation.

Abstract

Dipolar-octupolar (DO) pyrochlore systems Ce$_2$(Zr,Sn,Hf)$_2$O$_7$ have garnered much attention as recent investigations suggest that they may stabilize a novel quantum spin ice (QSI), a quantum spin liquid (QSL) with an emergent $U(1)$ gauge field. In particular, the experimentally estimated microscopic exchange parameters place Ce$_2$Zr$_2$O$_7$ in the $\pi$-flux QSI regime, and recent neutron scattering experiments have corroborated some key theoretical predictions. On the other hand, to make a definitive conclusion, more multifaceted experimental signatures are desirable. In this regard, recent neutron scattering investigation of the magnetic field dependence of the spin correlations in Ce$_2$Zr$_2$O$_7$ may provide valuable information. However, there have not been any comprehensive theoretical studies for comparison. In this work, we provide such information using gauge mean-field theory (GMFT), allowing for theoretical investigation beyond the perturbative regime. In particular, we construct the phase diagrams for the [110], [111], and [001] field directions. Furthermore, we demonstrate the distinctive evolution of the equal-time and dynamical spin structure factors as a function of the magnetic field for each field direction. These predictions will help future experiments confirm the true nature of the DO-QSI.