Novel Magnetoacoustic Resonance Technique for Exploring Hidden Quadrupoles in a Crystal Field Quartet

TL;DR

This paper introduces a new magnetoacoustic resonance method combining acoustic strain and microwave fields to probe quadrupoles in crystal field quartets, enabling quantum transitions inaccessible by traditional acoustic methods.

Contribution

The paper presents a novel technique that integrates magnetoacoustic resonance with Floquet theory to study quadrupole physics in crystal field systems, expanding experimental capabilities.

Findings

Identification of transition probability maxima linked to propagation directions

Demonstration of abrupt changes due to induced ordered moments

Potential for broader applications in quadrupole physics research

Abstract

Crystal field quartets with quadrupole degrees of freedom play a crucial role in hidden ordering systems, as exemplified by CeB$_6$. We present a novel magnetoacoustic resonance technique that combines acoustically induced strain fields with a linearly polarized high-frequency microwave field to probe quadrupoles inherent in the quartet hidden behind magnetic properties. This method offers the advantage of enabling quantum quadrupole resonance transitions for large excitation energy gaps within quartet sublevels under a strong magnetic field, which cannot be achieved by acoustic experiments alone. Formulating a simultaneous single-phonon-single-photon absorption transition process using Floquet theory, we demonstrate how the transition probabilities are affected by changing the propagation direction of a bulk acoustic wave. The key result is that distinct maxima in transition probabilities, attributed to specific propagation directions, indicate a characteristic of quadrupole physics and exhibit an abrupt change owing to an induced ordered moment. This photon-assisted magnetoacoustic resonance technique will promote a broader range of applications of acoustic experiments for the study of quadrupole physics.