Abstract

The generation process of second harmonic (SH) radiation from holes periodically arranged on a metal surface is investigated. Three main modulating factors affecting the optical response are identified: the near-field distribution at the wavelength of the fundamental harmonic, how SH light couples to the diffraction orders of the lattice, and its propagation properties inside the holes. It is shown that light generated at the second harmonic can excite electromagnetic modes otherwise inaccessible in the linear regime under normal incidence illumination. It is demonstrated that the emission of SH radiation is only allowed along off-normal paths precisely due to that symmetry. Two different regimes are studied in the context of extraordinary optical transmission, where enhanced linear transmission either occurs through localized electromagnetic modes or is aided by surface plasmon polaritons (SPPs). While localized resonances in metallic hole arrays have been previously investigated, the role played by SPPs in SH generation has not been addressed so far. In general, good agreement is found between our calculations (based on the finite difference time domain method) and the experimental results on localized resonances, even though no free fitting parameters were used in describing the materials. It is found that SH emission is strongly modulated by enhanced fields at the fundamental wavelength (either localized or surface plasmon modes) on the glass metal interface. This is so in the transmission side but also in reflection, where emission can only be explained by an efficient tunneling of SH photons through the holes from the output to the input side. Finally, the existence of a dark SPP at the fundamental field is identified through a noninvasive method for the first time, by analyzing the efficiency and far-field pattern distribution in transmission at the second harmonic.

Highlights

  • Second-harmonic generation (SHG) is a nonlinear process that creates a single photon at λ∕2 through the interaction of two photons of wavelength λ [1]

  • We have conducted finite difference time domain (FDTD) calculations to compare with existing experimental works, where the effect of localized resonances in SHG was studied

  • We have investigated the role played by surface plasmon polaritons on SHG from rectangular hole arrays (RHAs), which has not been previously discussed, to the best of our knowledge

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Summary

INTRODUCTION

Second-harmonic generation (SHG) is a nonlinear process that creates a single photon at λ∕2 through the interaction of two photons of wavelength λ [1]. Nanostructured metal films locally enhance the intensity of the incident field, which might be useful to obtain SHG at less demanding laser powers. This is the case of an array of holes drilled in a metal film, a nanostructured system that has been widely investigated in the linear regime especially since the discovery of extraordinary optical transmission (EOT) [33]. In particular we are interested in the seminal work by Nieuwstadt and coworkers [36] on SHG emission from twodimensional rectangular hole arrays (RHAs) carved on gold films (see Fig. 1) They found SH enhancement due to localized modes occurring close to the cutoff wavelength of the fundamental harmonic (FH) field, λc.

THEORETICAL APPROACH
Symmetry of Second-Harmonic Fields
FAR-FIELD EMISSION AT SECONDHARMONIC
Field Distribution at Fundamental Harmonic
Propagation inside the Holes at Second Harmonic
SPP-Related Effects
Localized Resonances and Related Effects
Findings
CONCLUSIONS

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