Low-field magnetotransport in graphene cavity devices

G. Q. Zhang, N. Kang, J. Y. Li, Li Lin, Hailin Peng, Zhongfan Liu, H. Q. Xu

Research output: Contribution to journalArticlepeer-review

Abstract

Confinement and edge structures are known to play significant roles in the electronic and transport properties of two-dimensional materials. Here, we report on low-temperature magnetotransport measurements of lithographically patterned graphene cavity nanodevices. It is found that the evolution of the low-field magnetoconductance characteristics with varying carrier density exhibits different behaviors in graphene cavity and bulk graphene devices. In the graphene cavity devices, we observed that intravalley scattering becomes dominant as the Fermi level gets close to the Dirac point. We associate this enhanced intravalley scattering to the effect of charge inhomogeneities and edge disorder in the confined graphene nanostructures. We also observed that the dephasing rate of carriers in the cavity devices follows a parabolic temperature dependence, indicating that the direct Coulomb interaction scattering mechanism governs the dephasing at low temperatures. Our results demonstrate the importance of confinement in carrier transport in graphene nanostructure devices.

Original languageEnglish
Article number205707
JournalNanotechnology
Volume29
Issue number20
DOIs
Publication statusPublished - 2018 Mar 23

Subject classification (UKÄ)

  • Condensed Matter Physics

Free keywords

  • grapheme
  • graphene nanostructures
  • phase coherent transport
  • weak localization

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