Abstract
Tungsten ditelluride (WTe2) is an atomically layered transition metal dichalcogenide whose physical properties change systematically from monolayer to bilayer and few-layer versions. In this report, we use apertureless scattering-type near-field optical microscopy operating at Terahertz (THz) frequencies and cryogenic temperatures to study the distinct THz range electromagnetic responses of mono-, bi- and trilayer WTe2 in the same multi-terraced micro-crystal. THz nano-images of monolayer terraces uncovered weakly insulating behavior that is consistent with transport measurements. The near-field signal on bilayer regions shows moderate metallicity with negligible temperature dependence. Subdiffractional THz imaging data together with theoretical calculations involving thermally activated carriers favor the semimetal scenario with Delta approx -10,{{{rm{meV}}}} over the semiconductor scenario for bilayer WTe2. Also, we observed clear metallic behavior of the near-field signal on trilayer regions. Our data are consistent with the existence of surface plasmon polaritons in the THz range confined to trilayer terraces in our specimens. Finally, data for microcrystals up to 12 layers thick reveal how the response of a few-layer WTe2 asymptotically approaches the bulk limit.
Highlights
Tungsten ditelluride (WTe2) is an atomically layered transition metal dichalcogenide whose physical properties change systematically from monolayer to bilayer and few-layer versions
Angle resolved photoemission spectroscopy (ARPES), revealed that bilayers could be weakly semimetallic with a small negative gap[12]
We conclude that trilayer and thicker specimens are metallic and host surface plasmon polaritons (SPP)[19,20] that dominate the response in the terahertz (THz) range
Summary
Tungsten ditelluride (WTe2) is an atomically layered transition metal dichalcogenide whose physical properties change systematically from monolayer to bilayer and few-layer versions. We use apertureless scattering-type near-field optical microscopy operating at Terahertz (THz) frequencies and cryogenic temperatures to study the distinct THz range electromagnetic responses of mono-, bi- and trilayer WTe2 in the same multi-terraced microcrystal. Our data are consistent with the existence of surface plasmon polaritons in the THz range confined to trilayer terraces in our specimens. We conclude that trilayer and thicker specimens are metallic and host surface plasmon polaritons (SPP)[19,20] that dominate the response in the terahertz (THz) range. Bulk WTe2 exhibits high electronic mobility and its intraband (Drude) optical response is entirely contained in the THz region[21,22].
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