Beams of light and wave effects .

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SUMMARY

This discussion focuses on the diffraction and interference of light waves, drawing parallels with water waves in a ripple tank. It establishes that both light and water waves are governed by the same wave equation, U_{tt} = αU_{xx}, leading to similar diffraction behaviors. The key factor in observing these effects in light is coherence; when light waves are coherent, diffraction and interference patterns are pronounced, while decreased coherence results in diminished visibility of these effects.

PREREQUISITES
  • Understanding of wave equations, specifically U_{tt} = αU_{xx}
  • Knowledge of wave phenomena such as diffraction and interference
  • Familiarity with the concept of coherence in wave physics
  • Experience with ripple tank experiments for visualizing wave behavior
NEXT STEPS
  • Research the principles of coherence in wave physics
  • Explore advanced diffraction patterns in light using laser sources
  • Study the mathematical derivation of the wave equation U_{tt} = αU_{xx}
  • Investigate the impact of varying frequencies on wave interference
USEFUL FOR

Students and educators in physics, optical engineers, and anyone interested in the principles of wave behavior and light phenomena.

Cheman
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Beams of light and wave effects...

Let us first think of a ripple tank and how this is used to demonstrate diffraction nad interference- this is one wave front so when passes through small gap curves the wavefront, spreads the wave out and thus causes diffraction. We often use this analogy to describe light.

But surely a beam of light is very different to a water wave for the simple reason that it is not just one wave but lots of wave chains traveling together in a beam. So how do we explain why diffraction of a beam of light is the same as you would expect from 1 single wave like a water wave?

Thanks in advance. :-)
 
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Suppose you had multiple sources of water waves, would you not still observe the diffraction through a single slot? The presence of waves of differing frequency's do not effect diffraction effects, only make it harder to see clearly. That means that the wave patterns in your wave tank will be very complex.

Both cases of waves, water and light are modeled by the same differential equation, in a single spatial dimension the wave equation is:

[tex]U_{tt} = \alpha U_{xx}[/tex]

Since the waves obey the same mathematics, why would we expect them to behave differently?
 
Cheman said:
Let us first think of a ripple tank and how this is used to demonstrate diffraction nad interference- this is one wave front so when passes through small gap curves the wavefront, spreads the wave out and thus causes diffraction. We often use this analogy to describe light.

But surely a beam of light is very different to a water wave for the simple reason that it is not just one wave but lots of wave chains traveling together in a beam. So how do we explain why diffraction of a beam of light is the same as you would expect from 1 single wave like a water wave?

Thanks in advance. :-)

The key in seeing these interference and diffraction effects with light is coherence. If all the "wave chains" are in phase with each other (ie. coherent), then these effects are easily visible and the behavior is identical to waves in a ripple tank. As the light becomes less coherent, these effects can become washed out.
 

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