Ultrafast Science (Jan 2021)

Polarization Flipping of Even-Order Harmonics in Monolayer Transition-Metal Dichalcogenides

  • Yuki Kobayashi,
  • Christian Heide,
  • Hamed Koochaki Kelardeh,
  • Amalya Johnson,
  • Fang Liu,
  • Tony F. Heinz,
  • David A. Reis,
  • Shambhu Ghimire

DOI
https://doi.org/10.34133/2021/9820716
Journal volume & issue
Vol. 2021

Abstract

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We present a systematic study of the crystal-orientation dependence of high-harmonic generation in monolayer transition-metal dichalcogenides, WS2 and MoSe2, subjected to intense linearly polarized midinfrared laser fields. The measured spectra consist of both odd- and even-order harmonics, with a high-energy cutoff extending beyond the 15th order for a laser-field strength around ~1 V/nm. In WS2, we find that the polarization direction of the odd-order harmonics smoothly follows that of the laser field irrespective of the crystal orientation, whereas the direction of the even-order harmonics is fixed by the crystal mirror planes. Furthermore, the polarization of the even-order harmonics shows a flip in the course of crystal rotation when the laser field lies between two of the crystal mirror planes. By numerically solving the semiconductor Bloch equations for a gapped-graphene model, we qualitatively reproduce these experimental features and find the polarization flipping to be associated with a significant contribution from interband polarization. In contrast, high-harmonic signals from MoSe2 exhibit deviations from the laser-field following of odd-order harmonics and crystal-mirror-plane following of even-order harmonics. We attribute these differences to the competing roles of the intraband and interband contributions, including the deflection of the electron-hole trajectories by nonparabolic crystal bands.