# Ultrafast Laser‐Induced Interatomic Forces in Magnetostrictive Metals

**Authors:** Xiaoxue Zeng, Lei Zhang, Yu Huang, Qingjie Fang, Yaokai Niu, Qiye Wen, Peng Yan, Zhifeng Chen, Zhiyong Zhong, Lichuan Jin

PMC · DOI: 10.1002/advs.202517754 · Advanced Science · 2025-11-23

## TL;DR

Researchers observed ultrafast changes in interatomic forces in magnetostrictive metals using laser pulses, revealing new insights into how these forces affect material behavior.

## Contribution

Direct observation of femtosecond-scale interatomic force changes in magnetostrictive FeGa thin films using optical birefringence.

## Key findings

- A transient signal of ≈400 fs is observed during demagnetization, influenced by external magnetic fields.
- The signal is attributed to ultrafast stress release due to suppressed magnetostriction.
- This reveals a nonequilibrium force state before lattice expansion occurs.

## Abstract

Femtosecond photoexcitation can abruptly redistribute electrons and trigger a series of transient nonequilibrium processes, among which ultrafast interatomic forces play a pivotal role in determining the structural and functional characteristics of solids. While ultrafast interatomic forces and their associated lattice dynamics have been extensively examined in semiconductors, experimental investigations of these nonequilibrium dynamics in metals remain lacking. To address this scientific gap, herein the direct observation of femtosecond‐scale variations in photoinduced ultrafast interatomic forces within wrinkled giant magnetostrictive FeGa thin films is presented. At the onset of demagnetization, a transient signal emerges, lasting ≈400 fs, with its orientation is influenced by the external magnetic field. Theoretical analysis indicates that this signal arises from the swift release of internal stress prompted by the suppression of magnetostriction during ultrafast demagnetization. Owing to magnetization‐induced stress anisotropy, this transient alteration in the interatomic potential introduces additional birefringence to the probe light. Consequently, this signal is attributed to a transient distortion of interatomic forces induced by the abrupt electron redistribution, establishing a nonequilibrium force state before any observable lattice expansion. These findings provide direct evidence for the existence of sub‐picosecond interatomic forces and suggest a novel approach to control metal lattice dynamics through ultrafast magnetostriction.

This study reports ultrafast changes in the interatomic forces generated by femtosecond laser excitation in magnetostrictive FeGa thin films. This ultrafast process manifests as an optical birefringence signal lasting ≈400 fs. Using a pump‐probe system, the femtosecond evolution of this nonequilibrium interatomic interaction is visualized, providing new insights into ultrafast demagnetization and related atomic dynamics.

## Full-text entities

- **Chemicals:** FeGa (-)

## Full text

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## Figures

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## References

68 references — full list in the complete paper: https://tomesphere.com/paper/PMC12884780/full.md

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Source: https://tomesphere.com/paper/PMC12884780