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Main Authors: Scharf, Gili, Hasharoni, Tomer, Donval, Lara, Gur, Leah Ben, Ron, Alon
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2503.10757
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author Scharf, Gili
Hasharoni, Tomer
Donval, Lara
Gur, Leah Ben
Ron, Alon
author_facet Scharf, Gili
Hasharoni, Tomer
Donval, Lara
Gur, Leah Ben
Ron, Alon
contents Anharmonic lattice vibrations play a key role in many physical phenomena. They govern the heat conductivity of solids, strongly affect the phonon spectra, play a prominent role in soft mode phase transitions, allow ultrafast engineering of material properties and more. The most direct evidence for anharmonicity is to measure the oscillation frequency changing as a function of the oscillation amplitude. For lattice vibrations, this is not a trivial task, and anharmonicity is probed indirectly through its effects on thermodynamic properties and spectral features or through coherent decay of one mode to another. However, measurement and control of the anharmonicity of a single Raman mode is still lacking. We show that ultrafast double pump-probe spectroscopy could be used to directly observe frequency shifts of Raman phonons as a function of the oscillation amplitude and disentangle the coherent contributions from quasi-harmonic sources such as temperature and changes to the carrier density in the thermoelectric materials SnTe and SnSe. Moreover, we show that coherent displacive phononic excitations in tandem with electron-phonon coupling is a pathway to dynamically control phonon anharmonicity. Our results have dramatic implications for the material engineering of future thermoelectrics. Moreover, our methodology could be used to isolate the basic mechanisms driving optically induced phase transitions and other nonlinear phenomena based on their unique timestamps.
format Preprint
id arxiv_https___arxiv_org_abs_2503_10757
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Coherent control through phonon anharmonicity
Scharf, Gili
Hasharoni, Tomer
Donval, Lara
Gur, Leah Ben
Ron, Alon
Materials Science
Mesoscale and Nanoscale Physics
Anharmonic lattice vibrations play a key role in many physical phenomena. They govern the heat conductivity of solids, strongly affect the phonon spectra, play a prominent role in soft mode phase transitions, allow ultrafast engineering of material properties and more. The most direct evidence for anharmonicity is to measure the oscillation frequency changing as a function of the oscillation amplitude. For lattice vibrations, this is not a trivial task, and anharmonicity is probed indirectly through its effects on thermodynamic properties and spectral features or through coherent decay of one mode to another. However, measurement and control of the anharmonicity of a single Raman mode is still lacking. We show that ultrafast double pump-probe spectroscopy could be used to directly observe frequency shifts of Raman phonons as a function of the oscillation amplitude and disentangle the coherent contributions from quasi-harmonic sources such as temperature and changes to the carrier density in the thermoelectric materials SnTe and SnSe. Moreover, we show that coherent displacive phononic excitations in tandem with electron-phonon coupling is a pathway to dynamically control phonon anharmonicity. Our results have dramatic implications for the material engineering of future thermoelectrics. Moreover, our methodology could be used to isolate the basic mechanisms driving optically induced phase transitions and other nonlinear phenomena based on their unique timestamps.
title Coherent control through phonon anharmonicity
topic Materials Science
Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2503.10757