Softening Mechanism of Coherent Phonons in Antimony Under High Density Photoexcitation

TL;DR

This study investigates how high-density photoexcitation affects the softening and recovery of coherent phonons in antimony, revealing that laser-induced structural changes govern the phonon softening mechanism.

Contribution

It provides new insights into impulsive phonon softening and recovery dynamics, linking them to laser-induced structural lattice changes in antimony.

Findings

Phonon frequency exhibits abrupt change and overshoot during recovery.

Initial phonon frequency correlates with high-pressure Raman shifts.

Structural lattice contraction and expansion govern phonon softening.

Abstract

We have investigated the dynamical properties of coherent phonons generated in antimony under high density photo excitation. Precise measurements and extended analysis of coherent phonon oscillations provide new insights into the process of impulsive softening. In the process of recovering from instantaneous softening, phonon frequency shows an unexpected temporal evolution involving an abrupt change and a slight overshoot. Moreover, fluence dependence of the initial phonon frequency is strongly correlated with the phonon frequency shift of the high-pressure Raman spectra. These results clearly prove that the structural changes (lattice contraction and expansion) induced by laser excitation governs the softening mechanism of coherent phonons.