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Universal slow plasmons and giant field enhancement in atomically thin quasi-two-dimensional metals

Felipe H. Jornada, Lede Xian, Angel Rubio () and Steven G. Louie ()
Additional contact information
Felipe H. Jornada: University of California at Berkeley
Lede Xian: Max Planck Institute for the Structure and Dynamics of Matter and Center for Free-Electron Laser Science
Angel Rubio: Max Planck Institute for the Structure and Dynamics of Matter and Center for Free-Electron Laser Science
Steven G. Louie: University of California at Berkeley

Nature Communications, 2020, vol. 11, issue 1, 1-10

Abstract: Abstract Plasmons depend strongly on dimensionality: while plasmons in three-dimensional systems start with finite energy at wavevector q = 0, plasmons in traditional two-dimensional (2D) electron gas disperse as $$\omega _p \sim \sqrt q$$ωp~q. However, besides graphene, plasmons in real, atomically thin quasi-2D materials were heretofore not well understood. Here we show that the plasmons in real quasi-2D metals are qualitatively different, being virtually dispersionless for wavevectors of typical experimental interest. This stems from a broken continuous translational symmetry which leads to interband screening; so, dispersionless plasmons are a universal intrinsic phenomenon in quasi-2D metals. Moreover, our ab initio calculations reveal that plasmons of monolayer metallic transition metal dichalcogenides are tunable, long lived, able to sustain field intensity enhancement exceeding 107, and localizable in real space (within ~20 nm) with little spreading over practical measurement time. This opens the possibility of tracking plasmon wave packets in real time for novel imaging techniques in atomically thin materials.

Date: 2020
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DOI: 10.1038/s41467-020-14826-8

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