Slow, Nanometer Light Confinement Observed in Atomically Thin TaS2

Abstract

Extreme light confinement down to the atomic scale has been theoretically predicted for ultrathin, Ta-based transition metal dichalcogenides (TMDs). In this work, we experimentally demonstrate in 2H-TaS2 monolayers and bilayers a lateral confinement ratio up to 300 at large wave vectors of q = 0.15 \, A-1, and slow light behaviour with a group velocity 10-4c. Quantitative momentum-resolved electron energy loss spectroscopy (q-EELS) with a momentum resolution of 0.0056 \, A-1 was used as a platform for the nanoscale optical measurements. With it, momentum-dispersed, two-dimensional (2D) plasmon resonances were experimentally observed, showing a transition from 2D to 3D Coulomb interaction in the high-momentum regime, equivalent to light confinement volumes of 1-2 \, nm3. Remarkably, the resonant modes do not enter the electron-hole continuum, predicting even further enhanced optical field confinements for this material at cryogenic temperatures.

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