# Observation of spin-phonon coupling in GdCl3 filled carbon nanotubes

**Authors:** S. Ncube, R. Erasmus, and S. Bhattacharyya

arXiv: 1906.01281 · 2019-06-05

## TL;DR

This study demonstrates enhanced spin-phonon coupling in gadolinium-filled carbon nanotubes, revealing a superparamagnetic phase transition below 100 K and phonon hardening near the transition, indicating strong spin-phonon interactions.

## Contribution

It provides experimental evidence of enhanced spin-phonon coupling in GdCl3-filled carbon nanotubes using magnetometry and Raman spectroscopy, highlighting a phase transition and phonon behavior.

## Key findings

- Superparamagnetic phase transition below 100 K
- Phonon hardening near 47 K
- Resonance between phonon mode and spin flip frequency

## Abstract

The enhancement of spin-phonon coupling in gadolinium filled double walled carbon nanotubes (GdCl3@DWNTs) is demonstrated through temperature dependent magnetrometry and polarized Raman Spectroscopy (PRS). Temperature dependent susceptibility measurements show that the GdCl3@DWNTs undergo a superparamagnetic phase transion at temperatures below 100 K with a blocking temperature at approximately 47 K. From the temperature dependent PRS, it is observed that a distinct phonon hardening occurs for the G-band modes at temperatures close to the onset of the superparamagentic phase. This is in contract to pristine DWNTs where phonon modes saturates to a constant frequency at low temperatures. The abrupt increase in phonon frequency is indicative of a pronounced spin-phonon coupling. The enhanced coupling in the GdCl3@DWNTs is believed to occur due to resonance between nanotube phonon mode and spin flip frequency as temperature decreases.

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Source: https://tomesphere.com/paper/1906.01281