Nature Communications (Feb 2024)

Electron/infrared-phonon coupling in ABC trilayer graphene

  • Xiaozhou Zan,
  • Xiangdong Guo,
  • Aolin Deng,
  • Zhiheng Huang,
  • Le Liu,
  • Fanfan Wu,
  • Yalong Yuan,
  • Jiaojiao Zhao,
  • Yalin Peng,
  • Lu Li,
  • Yangkun Zhang,
  • Xiuzhen Li,
  • Jundong Zhu,
  • Jingwei Dong,
  • Dongxia Shi,
  • Wei Yang,
  • Xiaoxia Yang,
  • Zhiwen Shi,
  • Luojun Du,
  • Qing Dai,
  • Guangyu Zhang

DOI
https://doi.org/10.1038/s41467-024-46129-7
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 6

Abstract

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Abstract Stacking order plays a crucial role in determining the crystal symmetry and has significant impacts on electronic, optical, magnetic, and topological properties. Electron-phonon coupling, which is central to a wide range of intriguing quantum phenomena, is expected to be intricately connected with stacking order. Understanding the stacking order-dependent electron-phonon coupling is essential for understanding peculiar physical phenomena associated with electron-phonon coupling, such as superconductivity and charge density waves. In this study, we investigate the effect of stacking order on electron-infrared phonon coupling in graphene trilayers. By using gate-tunable Raman spectroscopy and excitation frequency-dependent near-field infrared nanoscopy, we show that rhombohedral ABC-stacked trilayer graphene has a significant electron-infrared phonon coupling strength. Our findings provide novel insights into the superconductivity and other fundamental physical properties of rhombohedral ABC-stacked trilayer graphene, and can enable nondestructive and high-throughput imaging of trilayer graphene stacking order using Raman scattering.