# Direct Evidence of Torque-mediated Optical Magnetism

**Authors:** M. Tuan Trinh, Krishnandu Makhal, Elizabeth F.C. Dreyer, Apoorv, Shanker, Seong-Jun Yoon, Jinsang Kim, and Stephen C. Rand

arXiv: 1905.00552 · 2019-05-03

## TL;DR

This study provides experimental evidence that optical magnetism can be enhanced through torque mechanisms at the molecular level, independent of spin interactions, confirmed by inelastic scattering spectra matching quantum theory.

## Contribution

It demonstrates the direct observation of torque-driven optical magnetism and identifies inelastic librational features in light scattering spectra, supporting a new mechanism for optical magnetism.

## Key findings

- Torque accounts for inelastic magnetic scattering components.
- Inelastic librational features are observed in cross-polarized spectra.
- Results align with quantum theoretical predictions.

## Abstract

We report experimental evidence of a mechanism that supports and intensifies induced magnetization at optical frequencies without the intervention of spin-orbit or spin-spin interactions. Energy-resolved spectra of scattered light, recorded at moderate intensities (108 W/cm2) and short timescales (<150 fs) in a series of non-magnetic molecular liquids, reveal the signature of torque dynamics driven jointly by the electric and magnetic field components of light at the molecular level. While past experiments have recorded radiant magnetization from magneto-electric interactions of this type, no evidence has been provided to date of the inelastic librational features expected in cross-polarized light scattering spectra due to the Lorentz force acting in combination with optical magnetic torque. Here, torque is shown to account for inelastic components in the magnetic scattering spectrum under conditions that produce no such features in electric dipole scattering, in excellent agreement with quantum theoretical predictions

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Source: https://tomesphere.com/paper/1905.00552