Abstract
Near-field imaging is a powerful tool to investigate the complex structure of light at the nanoscale. Recent advances in near-field imaging have indicated the possibility for the complete reconstruction of both electric and magnetic components of the evanescent field. Here we study the electro-magnetic field structure of surface plasmon polariton waves propagating along subwavelength gold nanowires by performing phase- and polarization-resolved near-field microscopy in collection mode. By applying the optical reciprocity theorem, we describe the signal collected by the probe as an overlap integral of the nanowire’s evanescent field and the probe’s response function. As a result, we find that the probe’s sensitivity to the magnetic field is approximately equal to its sensitivity to the electric field. Through rigorous modeling of the nanowire mode as well as the aperture probe response function, we obtain a good agreement between experimentally measured signals and a numerical model. Our findings provide a better understanding of aperture-based near-field imaging of the nanoscopic plasmonic and photonic structures and are helpful for the interpretation of future near-field experiments.
Highlights
Near-field imaging is a powerful tool to investigate the complex structure of light at the nanoscale
In one of the near-field measurement techniques, known as near-field scanning optical microscopy (NSOM)[7], the detection is usually done by frustrating the evanescent field and converting it into far-field radiation by means of a scattering probe (s-NSOM) or a light-collecting aperture probe (a-NSOM)
As for photonic crystal waveguides (PhCWs), here we find that the probe sensitivity to the electric field is approximately equal to its sensitivity to the magnetic field
Summary
Near-field imaging is a powerful tool to investigate the complex structure of light at the nanoscale. We study the electro-magnetic field structure of surface plasmon polariton waves propagating along subwavelength gold nanowires by performing phase- and polarization-resolved near-field microscopy in collection mode. Several geometries, including plasmonic wires and tapers[13,14,15], nanoparticles[16] and holes[17,18,19,20], have been studied using NSOM In these studies the signal collected by the near-field aperture probe was always attributed to the electric field. A study performed on photonic crystal waveguides (PhCWs) has shown that the probe sensitivity to the electric field component near a PhCW is approximately the same as that to the magnetic field.
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