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S Huang, M Leblanc, M M Ohn

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    Fiber-optic Bragg gratings can detect strain gradients by analyzing spectral distortions. This technology enables quasi-distributed strain sensing and warns of sensor/host debonding.

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    Area of Science:

    • Optical Engineering
    • Materials Science
    • Structural Health Monitoring

    Background:

    • Fiber-optic Bragg gratings are sensitive to strain.
    • Strain gradients can cause spectral distortions in Bragg gratings.
    • Existing methods may not fully capture strain gradient effects.

    Purpose of the Study:

    • To investigate the impact of strain gradients on fiber-optic Bragg grating spectra.
    • To validate the use of Bragg gratings as quasi-distributed strain sensors.
    • To explore novel applications in structural sensing.

    Main Methods:

    • Utilized J-matrix formalism for theoretical calculations.
    • Performed experimental measurements of Bragg grating spectra under strain gradients.
    • Analyzed spectral shifts and distortions.

    Main Results:

    • Strain gradients cause both spectral shifts and distortions (chirp).
    • Experimental results confirmed theoretical predictions.
    • Intracore Bragg gratings accurately evaluate strain gradients.

    Conclusions:

    • Bragg gratings function as quasi-distributed strain sensors.
    • This technique enhances structural sensing capabilities.
    • It provides early detection of sensor/host debonding.