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Characterisation of periodically poled materials using nonlinear microscopy.

John Harris1, Greg Norris, Gail McConnell

  • 1Centre for Biophotonics, Strathclyde Institute for Pharmacy and Biomedical Sciences, University of Strathclyde, 27 Taylor St, Glasgow G4 0NR, United Kingdom. j.harris@strath.ac.uk

Optics Express
|June 11, 2008
PubMed
Summary

Multi-photon laser scanning luminescence microscopy offers high-resolution, minimally-invasive imaging for fabricating advanced crystalline materials. This technique provides crucial internal structure insights for optimal performance in nonlinear optical applications.

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Area of Science:

  • Materials Science
  • Optical Engineering
  • Photonics

Background:

  • Periodically poled crystalline materials are vital for high-efficiency nonlinear optical processes like second harmonic generation and optical parametric generation.
  • Precise fabrication of sub-micron poled regions is essential for optimal device performance.

Purpose of the Study:

  • To introduce multi-photon laser scanning luminescence microscopy as a novel, minimally-invasive technique for characterizing periodically poled crystalline materials.
  • To compare the capabilities of multi-photon imaging with traditional confocal microscopy for analyzing internal device structures.

Main Methods:

  • Utilizing multi-photon laser scanning luminescence microscopy to image the internal structure of periodically poled crystalline materials.
  • Performing a comparative analysis between multi-photon and confocal imaging techniques.

Main Results:

  • Multi-photon microscopy provides high spatial resolution imaging of internal device structures.
  • The technique offers insights not readily achievable with existing methods, aiding in fabrication process optimization.

Conclusions:

  • Multi-photon laser scanning luminescence microscopy is a powerful tool for the detailed characterization of periodically poled crystalline materials.
  • This advanced imaging method supports the precise fabrication required for efficient nonlinear optical devices.