# Coherent modulation of the electron temperature and electron-phonon   couplings in a 2D material

**Authors:** Yingchao Zhang, Xun Shi, Wenjing You, Zhensheng Tao, Yigui Zhong,, Fairoja Cheenicode Kabeer, Pablo Maldonado, Peter M. Oppeneer, Michael Bauer,, Kai Rossnagel, Henry Kapteyn, Margaret Murnane

arXiv: 1906.09545 · 2020-05-01

## TL;DR

This study demonstrates how femtosecond laser pulses can coherently control electron and phonon interactions in a 2D material, enabling dynamic manipulation of its electronic properties through tailored light excitation.

## Contribution

It introduces a method to coherently modulate electron temperature and electron-phonon couplings in a 2D charge density wave material using ultrafast laser pulses, revealing tunable energy exchange mechanisms.

## Key findings

- Controlled electron temperature modulation from 200 K to 1000 K.
- Observation of a phase change indicating switching of coupling mechanisms.
- Demonstration of light-induced coherent manipulation of material interactions.

## Abstract

Ultrashort light pulses can selectively excite charges, spins and phonons in materials, providing a powerful approach for manipulating their properties. Here we use femtosecond laser pulses to coherently manipulate the electron and phonon distributions, and their couplings, in the charge density wave (CDW) material 1T-TaSe$_2$. After exciting the material with a short light pulse, spatial smearing of the electrons launches a coherent lattice breathing mode, which in turn modulates the electron temperature. This indicates a bi-directional energy exchange between the electrons and the strongly-coupled phonons. By tuning the laser excitation fluence, we can control the magnitude of the electron temperature modulation, from ~ 200 K in the case of weak excitation, to ~ 1000 K for strong laser excitation. This is accompanied by a switching of the dominant mechanism from anharmonic phonon-phonon coupling to coherent electron-phonon coupling, as manifested by a phase change of $\pi$ in the electron temperature modulation. Our approach thus opens up possibilities for coherently manipulating the interactions and properties of quasi-2D and other quantum materials using light.

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Source: https://tomesphere.com/paper/1906.09545