Plasmons in metallic monolayer and bilayer transition metal dichalcogenides

Andersen, Kirsten; Thygesen, Kristian Sommer

doi:10.1103/physrevb.88.155128

Cited by 49 publications

(82 citation statements)

References 32 publications

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“…On the one side there are models combining effective k · p descriptions of the quadratic electronic bands around the band gap with an evaluation of the dielectric function within the random phase approximation 29,30 . On the other side, there are RPA descriptions based on full density functional theory calculations, which include realistic single particle band structures describing the complete Brillouin zone 32,[38][39][40][41][42] . Here, we add a third approach by utilizing a materialspecific low-energy model Hamiltonian derived from ab initio calculations for the undoped material as the basis for the evaluation of dynamical response functions in the electron and hole doped situations.…”

Section: Discussionmentioning

confidence: 99%

Valley plasmonics in transition metal dichalcogenides

et al. 2016

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The rich phenomenology of plasmonic excitations in the dichalcogenides is analyzed as a function of doping. The many-body polarization, the dielectric response function and electron energy loss spectra are calculated using an ab initio based model involving material-realistic Coulomb interactions, band structure and spin-orbit coupling. Focusing on the representative case of MoS2, a plethora of plasmon bands are observed, originating from scattering processes within and between the conduction or valence band valleys. We discuss the resulting square-root and linear collective modes, arising from long-range versus short-range screening of the Coulomb potential. We show that the multi-orbital nature of the bands and spin-orbit coupling strongly affects inter-valley scattering processes by gapping certain two-particle modes at large momentum transfer.

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Section: Discussionmentioning

confidence: 99%

Valley plasmonics in transition metal dichalcogenides

et al. 2016

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“…[23], this property is related to the depolarization effect induced by crystal local fields. Finally, in the optical limit q < 0.02Å −1 , the plasmon frequency has a √ q dispersion [31].…”

Section: B Monolayersmentioning

confidence: 99%

Interplay between structure and electronic properties of layered transition-metal dichalcogenides: Comparing the loss function of1Tand2Hpolymorphs

2014

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Transition-metal dichalcogenides (TMD) share the same global layered structure, but distinct polymorphs are characterized by different local coordinations of the transition-metal atoms. Here we compared the 1T and 2H families of metallic TMD, both in the bulk and in the two-dimensional forms. By means of first-principles time-dependent density functional calculations of the loss function, we established the direct connection between the low-energy plasmon properties and the crystal-structure symmetry. The different atomic environments affect the d − d electron-hole excitations, which are prominent at low energies, resulting in distinct in-plane plasmon dispersions in the two families. Conversely, the different periodicity of the plasmon reappearance along the c axis perpendicular to the layers can be used to distinguish the various crystal structures of TMD.

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“…Localized surface plasmon resonances (LSPR) in metal nanoparticles have been utilized for chemical sensing [1], cancer treatment [2], and to increase solar cell performance [3]. Two-dimensional (2D) plasmons are found at metal surfaces and thin films [4], in graphene [5][6][7][8], and other atomically thin 2D materials such as metallic transition metal dichalcogenides [9].…”

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confidence: 99%