H. Yi, Zengle Huang, W. Shi, L. Min, R. Wu, C. Polley, Ruoxi Zhang, Yi-Fan Zhao, Ling Zhou, J. Adell, X. Gui, W. Xie, M. Chan, Z. Mao, Zhijun Wang, Weida Wu, Cui-Zu Chang
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Surface charge induced Dirac band splitting in a charge density wave material
(TaSe4)2I
(TaSe4)2I, a quasi-one-dimensional (1D) crystal, shows a characteristic temperature-driven metal-insulator phase transition. Above the charge density wave (CDW) temperature Tc, (TaSe4)2I has been predicted to harbor a Weyl semimetal phase. Below Tc, it becomes an axion insulator. Here, we perform angle-resolved photoemission spectroscopy (ARPES) measurements on the (110) surface of (TaSe4)2I and observe two sets of Dirac-like energy bands in the first Brillion zone, which agree well with our first-principles calculations. Moreover, we find that each Dirac band exhibits an energy splitting of hundreds of meV under certain circumstances. In combination with core level measurements, our theoretical analysis shows that this Dirac band splitting is a result of surface charge polarization due to the loss of surface iodine atoms. Our findings here shed new light on the interplay between band topology and CDW order in Peierls compounds and will motivate more studies on topological properties of strongly correlated quasi-1D materials.
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