Litcius/Paper detail

A Large Effective Phonon Magnetic Moment in a Dirac Semimetal

Bing Cheng, Timo Schumann, Youcheng Wang, X. Zhang, David Barbalas, Susanne Stemmer, N. P. Armitage

2020Nano Letters98 citationsDOI

Abstract

and observed a particularly low frequency optical phonon as well as a very prominent and field-sensitive cyclotron resonance. As the cyclotron frequency is tuned with the field to pass through the phonon, the phonon becomes circularly polarized, as shown by a notable splitting in its response to right- and left-hand polarized light. This splitting can be expressed as an effective phonon magnetic moment that is approximately 2.7 times the Bohr magneton, which is almost 4 orders of magnitude larger than ab initio calculations predict for phonon magnetic moments in nonmagnetic insulators. This exceedingly large value is due to the coupling of the phonons to the cyclotron motion and is controlled directly by the electron-phonon coupling constant. This field-tunable circular-polarization-selective coupling provides new functionality for nonlinear optics to create light-induced topological phases in Dirac semimetals.

Topics & Concepts

Condensed matter physicsSemimetalDirac (video compression format)PhononGrapheneMoment (physics)Magnetic momentPhysicsMaterials scienceQuantum mechanicsBand gapNeutrinoTopological Materials and PhenomenaGraphene research and applicationsQuantum Mechanics and Non-Hermitian Physics