Acoustic Phonon Dispersion Engineering in Bulk Crystals via Incorporation of Dopant Atoms

TL;DR

This study demonstrates that doping alumina crystals with Nd atoms significantly alters their acoustic phonon spectrum, offering a new approach for phonon engineering relevant to thermal and optoelectronic applications.

Contribution

It reveals that even low concentrations of Nd dopants can profoundly modify phonon dispersion in bulk crystals, a novel insight for phonon spectrum engineering.

Findings

Nd doping decreases transverse acoustic phonon velocity by ~600 m/s at 0.1% concentration

Phonon frequency and velocity changes are non-monotonic with doping levels

Doping modifies phonon spectra similarly to nanostructuring, impacting device design

Abstract

We report results of Brillouin - Mandelstam spectroscopy of transparent alumina crystals with Nd dopants. The ionic radius and atomic mass of Nd atoms are distinctively different from those of the host Al atoms. Our results show that even a small concentration of Nd atoms incorporated into the alumina samples produces a profound change in the acoustic phonon spectrum. The velocity of the transverse acoustic phonons decreases by ~600 m/s at the Nd density of only ~0.1 %. Interestingly, the decrease in the phonon frequency and velocity with the doping concentration is non-monotonic. The obtained results, demonstrating that modification of the acoustic phonon spectrum can be achieved not only by nanostructuring but also by doping have important implications for thermal management as well as thermoelectric and optoelectronic devices.