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Concurrent probing of electron-lattice dephasing induced by photoexcitation in 1T-TaSeTe using ultrafast electron diffraction

It has been technically challenging to concurrently probe the electrons and the lattices in materials during non-equilibrium processes, allowing their correlations to be determined. Here, in a single set of ultrafast electron diffraction patterns taken on the charge-density-wave (CDW) material 1T-TaSeTe, we discover a temporal shift in the diffraction intensity measurements as a function of scattering angle. With the help of dynamic models and theoretical calculations, we show that the ultrafast electrons probe both the valence-electron and lattice dynamic processes, resulting in the temporal shift measurements. Our results demonstrate unambiguously that the CDW is not merely a result of the periodic lattice deformation ever-present in 1T-TaSeTe but has significant electronic origin. This method demonstrates a novel approach for studying many quantum effects that arise from electron-lattice dephasing in molecules and crystals for next-generation devices.

preprint2020arXivOpen access
Jun LiJunjie LiKai SunLijun WuRenkai LiJie YangXiaozhe ShenXijie WangHuixia LuoRobert J. CavaIan K. RobinsonXilian JinWeiguo YinYimei ZhuJing Tao
cond-mat.mtrl-sci
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Open access15 authors1 topic
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Jun LiJunjie LiKai SunLijun WuRenkai LiJie YangXiaozhe ShenXijie WangHuixia LuoRobert J. CavaIan K. RobinsonXilian JinWeiguo YinYimei ZhuJing Tao

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