English

Enhanced third-order optical nonlinearity driven by surface-plasmon field gradients

Mesoscale and Nanoscale Physics 2018-05-23 v1

Abstract

Achieving efficient nonlinear optical frequency conversion in small volumes is key for future on-chip photonic devices that would provide a higher-speed alternative to modern electronics. However, the already intrinsically low conversion efficiency severely limits miniaturization to nanoscale dimensions. Here we demonstrate that gradient-field effects can provide for an efficient, conventionally dipole-forbidden nonlinear response, offering a new approach for enhanced nonlinear optics in nanostructures. We show that a {\em longitudinal} nonlinear source current can dominate the third-order optical nonlinearity of the free electron response in gold in the technologically important near-IR frequency range where the nonlinearities due to other mechanisms are particularly small. Using adiabatic nanofocusing to spatially confine the excitation fields, from measurements of the 2ω1ω22\omega_1 - \omega_2 four-wave mixing response as a function of detuning ω1ω2\omega_1 - \omega_2, we find up to 10510^{-5} conversion efficiency with a gradient field contribution to χAu(3)\chi^{(3)}_{\mathrm{Au}} of up to 1019 m2/V210^{-19}~\mathrm{m}^2 / \mathrm{V}^2. The results are in good agreement with theory based on plasma hydrodynamics. Our results demonstrate an increase in nonlinear conversion efficiency with decreasing sample size that can offset and even overcompensate the volume decrease of conventional dipolar pathways. This will enable more efficient nonlinear optical devices and frequency converters and facilitate the extension of coherent multidimensional spectroscopies to the nanoscale.

Keywords

Cite

@article{arxiv.1712.03357,
  title  = {Enhanced third-order optical nonlinearity driven by surface-plasmon field gradients},
  author = {Vasily Kravtsov and Sultan AlMutairi and Ronald Ulbricht and A. Ryan Kutayiah and Alexey Belyanin and Markus B. Raschke},
  journal= {arXiv preprint arXiv:1712.03357},
  year   = {2018}
}

Comments

14 pages, 4 figures

R2 v1 2026-06-22T23:13:03.958Z