Discovery of an unconventional charge modulation on the surface of charge-density-wave material TaTe4

Electronic systems with quasi-one-dimensional (Q1D) Fermi surface tend to form either a charge-density-wave (CDW) or a spin-density-wave ground state at low temperatures due to one-dimensional instabilities. Among various CDW states, surface CDWs are different from that within the bulk due to the re...

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Bibliographic Details
Published in:New journal of physics 2020-08, Vol.22 (8), p.083025
Main Authors: Sun, Haigen, Shao, Zhibin, Luo, Tianchuang, Gu, Qiangqiang, Zhang, Zongyuan, Li, Shaojian, Liu, Lijun, Gedeon, Habakubaho, Zhang, Xin, Bian, Qi, Feng, Ji, Wang, Jian, Pan, Minghu
Format: Article
Language:English
Subjects:
Charge density waves
Charge materials
Critical field (superconductivity)
Density functional theory
electron-electron interaction
Electronic systems
Energy gap
Fermi surface nesting
Fermi surfaces
Low temperature
Magnetic fields
Mathematical analysis
Modulation
Nesting
Periodic variations
Physics
scanning tunneling microscopy
Spin density waves
surface charge density wave
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Summary:Electronic systems with quasi-one-dimensional (Q1D) Fermi surface tend to form either a charge-density-wave (CDW) or a spin-density-wave ground state at low temperatures due to one-dimensional instabilities. Among various CDW states, surface CDWs are different from that within the bulk due to the reduced dimensionality. Here we report the systematic investigation of charge density modulation on the surface of in situ cleaved TaTe4 crystal by means of low temperature scanning tunneling microscopy/spectroscopy, corroborated with density functional theory calculation. Well-defined Q1D modulation (4a, 6c) accompanied with a periodic lattice distortion is clearly observed on the (010) cleaved surface, distinct from that of its bulk CDW (2a × 2a × 3c). Tunneling spectroscopic measurements reveal a partially-opened energy gap about 23 meV around Fermi level. Such gap shows similar spatial variation with the periodicity of surface modulation and diminishes subsequently as temperature rises, which indicates a novel surface-related CDW gap states. The surface modulation vectors fit well with the Fermi surface nesting vectors, derived from the calculated Fermi surfaces. Surprisingly, such surface modulation can be suppressed greatly by applying vertical magnetic field and a critical field about 9.05 T can be estimated from field-dependent data. Our results demonstrate that this unique CDW modulation is strongly related to Fermi surface nesting mediated electron-electron coupling due to the reduced dimensionality of the surface, and can be readily tuned by relatively small magnetic field.
ISSN:1367-2630
DOI:10.1088/1367-2630/aba065