Physical Review X (Apr 2020)

Light-Driven Raman Coherence as a Nonthermal Route to Ultrafast Topology Switching in a Dirac Semimetal

  • C. Vaswani,
  • L.-L. Wang,
  • D. H. Mudiyanselage,
  • Q. Li,
  • P. M. Lozano,
  • G. D. Gu,
  • D. Cheng,
  • B. Song,
  • L. Luo,
  • R. H. J. Kim,
  • C. Huang,
  • Z. Liu,
  • M. Mootz,
  • I. E. Perakis,
  • Y. Yao,
  • K. M. Ho,
  • J. Wang

DOI
https://doi.org/10.1103/PhysRevX.10.021013
Journal volume & issue
Vol. 10, no. 2
p. 021013

Abstract

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A grand challenge underlies the entire field of topology-enabled quantum logic and information science: how to establish topological control principles driven by quantum coherence and understand the time dependence of such periodic driving. Here we demonstrate a few-cycle THz-pulse-induced phase transition in a Dirac semimetal ZrTe_{5} that is periodically driven by vibrational coherence due to excitation of the lowest Raman active mode. Above a critical THz-pump field threshold, there emerges a long-lived metastable phase, approximately 100 ps, with unique Raman phonon-assisted topological switching dynamics absent for optical pumping. The switching also manifests itself by distinct features: nonthermal spectral shape, relaxation slowing near the Lifshitz transition where the critical Dirac point occurs, and diminishing signals at the same temperature that the Berry-curvature-induced anomalous Hall effect magnetoresistance vanishes. These results, together with first-principles modeling, identify a mode-selective Raman coupling that drives the system from strong to weak topological insulators with a Dirac semimetal phase established at a critical atomic displacement controlled by the phonon coherent pumping. Harnessing of vibrational coherence can be extended to steer symmetry-breaking transitions, i.e., Dirac to Weyl ones, with implications for THz topological quantum gate and error correction applications.