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Modes of Standing Waves - I01:03

Modes of Standing Waves - I

A close look at earthquakes provides evidence for the conditions appropriate for resonance, standing waves, and constructive and destructive interference. A building may vibrate for several seconds with a driving frequency matching the building's natural frequency of vibration; this produces a resonance that results in one building collapsing while the neighboring buildings do not. Often, buildings of a certain height are devastated, while other taller buildings remain intact. This phenomenon...
Carrier Generation and Recombination01:22

Carrier Generation and Recombination

Carrier generation is the process by which electron-hole pairs (EHPs) are created within the semiconductor. In direct-bandgap semiconductors, such as gallium arsenide (GaAs), this occurs efficiently when energy absorption prompts valence electrons to leap into the conduction band, leaving behind holes.
This process is given by the generation rate G and is efficient due to the conservation of momentum between the valence band maximum and conduction band minimum.
Indirect generation involves an...
Modes of Standing Waves: II01:04

Modes of Standing Waves: II

The starting point for expressing the modes of standing waves is understanding the boundary conditions that the waves must follow. The boundary conditions are derived from the physical understanding of how the standing waves are sustained, that is, how the vibrating particles of the medium behave at the boundaries imposed on them.
For a tube open at one end and closed at the other filled with air, the modes are such that there is always an antinode at the open end and a node at the closed end.

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Related Experiment Video

Updated: Jun 20, 2026

20 mJ, 1 ps Yb:YAG Thin-disk Regenerative Amplifier
10:17

20 mJ, 1 ps Yb:YAG Thin-disk Regenerative Amplifier

Published on: July 12, 2017

Second-harmonic generation in single-mode and multimode fibers.

M A Saifi, M J Andrejco

    Optics Letters
    |September 12, 2009
    PubMed
    Summary

    Efficient second-harmonic generation was achieved in telecommunication optical fibers. This process is linked to germania-related photosensitive color centers, particularly in fibers with germanium, phosphorous, and fluorine doping.

    Area of Science:

    • Photonics and Optical Engineering
    • Materials Science

    Background:

    • Second-harmonic generation (SHG) is a key nonlinear optical process.
    • Optical fibers are crucial for telecommunications and nonlinear optics.

    Purpose of the Study:

    • To investigate efficient second-harmonic generation in commercial optical fibers.
    • To identify the role of dopants and core properties in SHG efficiency.

    Main Methods:

    • Testing commercially available single-mode and multimode optical fibers.
    • Analyzing the effects of germanium, phosphorous, and fluorine dopants.
    • Correlating SHG efficiency with fiber core characteristics.

    Main Results:

    • Efficient SHG was observed in multiple telecommunication-grade optical fibers.

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    Last Updated: Jun 20, 2026

    20 mJ, 1 ps Yb:YAG Thin-disk Regenerative Amplifier
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    Published on: July 12, 2017

    Automation of Mode Locking in a Nonlinear Polarization Rotation Fiber Laser through Output Polarization Measurements
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    Automation of Mode Locking in a Nonlinear Polarization Rotation Fiber Laser through Output Polarization Measurements

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  • Germania-related photosensitive color centers were identified as crucial for efficient SHG.
  • A 1.5% conversion efficiency was achieved in doped single-mode fibers with high hydroxyl levels.
  • Conclusions:

    • Telecommunication optical fibers can be utilized for efficient second-harmonic generation.
    • Fiber doping, particularly with germanium, and the presence of hydroxyl groups significantly enhance SHG.
    • This research opens possibilities for integrated nonlinear photonic devices using existing fiber infrastructure.