Influence of the substrate material on the knife-edge based profiling of tightly focused light beams.

@article{Huber2016InfluenceOT,
  title={Influence of the substrate material on the knife-edge based profiling of tightly focused light beams.},
  author={C. Huber and Sergej Orlov and Peter Banzer and Gerd Leuchs},
  journal={Optics express},
  year={2016},
  volume={24 8},
  pages={
          8214-27
        }
}
The performance of the knife-edge method as a beam profiling technique for tightly focused light beams depends on several parameters, such as the material and height of the knife-pad as well as the polarization and wavelength of the focused light beam under study. Here we demonstrate that the choice of the substrate the knife-pads are fabricated on has a crucial influence on the reconstructed beam projections as well. We employ an analytical model for the interaction of the knife-pad with the… 
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References

SHOWING 1-10 OF 29 REFERENCES

Corrections to the knife-edge based reconstruction scheme of tightly focused light beams.

It is shown, that the actual beam shape and spot size of tightly focused beams can still be derived from knife-edge measurements for pure edge materials and different edge thicknesses by adapting the analysis method of the experimental data taking into account the interaction of the beam with the edge.

Interaction of highly focused vector beams with a metal knife-edge.

A deeper understanding of the interaction between the knife-edge and the incoming highly focused beam is gained in the theoretical model by considering eigenmodes of the metal-insulator-metal structure.

Measurement of submicron laser beam radii.

Three methods for direct measurement of the intensity distribution in laser beams focused by microscope optics to waists of submicron width are described and compared. They use scans of the beam

Nanointerferometric amplitude and phase reconstruction of tightly focused vector beams

Highly confined vectorial electromagnetic field distributions are an excellent tool for detailed studies in nano-optics, such as nonlinear microscopy1, advanced fluorescence imaging2,3 or

The focus of light—linear polarization breaks the rotational symmetry of the focal spot

Abstract We experimentally demonstrate for the first time that a linearly polarized beam is focused to an asymmetric spot when using a high-numerical aperture focusing system. This asymmetry was

Precision measurement of the electromagnetic fields in the focal region of a high-numerical-aperture lens using a tapered fiber probe.

It is shown that the measurement of the intensity around the focus of a N.A.-0.95 lens using a tapered optical fiber probe is consistent with vector diffraction theory when the probe properties are taken into account.

Diffractive arrays of gold nanoparticles near an interface: Critical role of the substrate

The optical properties of periodic arrays of plasmonic nanoantennas are strongly affected by coherent multiple scattering in the plane of the array, which leads to sharp spectral resonances in both

On the experimental investigation of the electric and magnetic response of a single nano-structure.

The developed experimental setup as well as the measurement techniques presented in this paper are a versatile tool to investigate the optical properties of single sub-wavelength nano-structures.

Extraordinary transmission through a single coaxial aperture in a thin metal film.

Enhanced transmission through a single sub-wavelength coaxial aperture illuminated with a strongly focused radially polarized light beam is reported and is in good agreement with finite difference time domain (FDTD) simulations.

Sharper focus for a radially polarized light beam.

We experimentally demonstrate for the first time that a radially polarized field can be focused to a spot size significantly smaller [0.16(1)lambda(2)] than for linear polarization (0.26lambda(2)).