Molecular Radiative Energy Shifts under Strong Oscillating Fields

Small. 2021 Jan;17(3):e2007244. doi: 10.1002/smll.202007244. Epub 2020 Dec 23.

Abstract

Coherent manipulation of light-matter interactions is pivotal to the advancement of nanophotonics. Conventionally, the non-resonant optical Stark effect is harnessed for band engineering by intense laser pumping. However, this method is hindered by the transient Stark shifts and the high-energy laser pumping which, by itself, is precluded as a nanoscale optical source due to light diffraction. As an analog of photons in a laser, surface plasmons are uniquely positioned to coherently interact with matter through near-field coupling, thereby, providing a potential source of electric fields. Herein, the first demonstration of plasmonic Stark effect is reported and attributed to a newly uncovered energy-bending mechanism. As a complementary approach to the optical Stark effect, it is envisioned that the plasmonic Stark effect will advance fundamental understanding of coherent light-matter interactions and will also provide new opportunities for advanced optoelectronic tools, such as ultrafast all-optical switches and biological nanoprobes at lower light power levels.

Keywords: energy shifts; light-matter interactions; optical stark effect; plexcitons; surface plasmons.

Publication types

  • Research Support, N.I.H., Extramural
  • Review

MeSH terms

  • Engineering
  • Lasers*
  • Photons*