# 1,000-Fold Enhancement of Light-Induced Magnetism in Plasmonic Au   Nanoparticles

**Authors:** Oscar Hsu-Cheng Cheng, Dong Hee Son, Matthew Sheldon

arXiv: 1904.11425 · 2020-03-18

## TL;DR

This study demonstrates a 1,000-fold enhancement of light-induced magnetism in plasmonic gold nanoparticles via the inverse Faraday effect, revealing ultrafast, coherent angular momentum transfer mechanisms with significant implications for optical control of magnetism.

## Contribution

First experimental quantification of optically induced magnetization in plasmonic gold nanoparticles showing a 1,000-fold increase over bulk gold and revealing ultrafast dynamics.

## Key findings

- Magnetization in Au nanoparticles is ~1,000x larger than in bulk gold.
- Magnetization and demagnetization occur within sub-picosecond timescales.
- Mechanism involves coherent transfer of angular momentum from circularly polarized light.

## Abstract

Strategies for ultrafast optical control of magnetism have been a topic of intense research for several decades because of the potential impact in technologies such as magnetic memory, spintronics, and quantum computation, as well as the opportunities for non-linear optical control and modulation in applications such as optical isolation and non-reciprocity. Here we report the first experimental quantification of optically induced magnetization in plasmonic Au nanoparticles due to the inverse Faraday effect (IFE). The induced magnetic moment in nanoparticles is found to be ~1,000x larger than that observed in bulk Au, and ~20x larger than the magnetic moment from optimized magnetic nanoparticle colloids such as magnetite. Furthermore, the magnetization and demagnetization kinetics are instantaneous within the sub-picosecond time resolution of our study, supporting a mechanism of coherent transfer of angular momentum from the circularly polarized excitation to the orbital angular momentum of the electron gas.

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Source: https://tomesphere.com/paper/1904.11425