Cherenkov radiation - phase velocity not group velocity

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SUMMARY

Cherenkov radiation occurs when a charged particle travels faster than the phase velocity of light in a medium, defined as v=c/n. This phenomenon arises because the phase of light cannot keep pace with the particle, preventing the formation of a static field around it. The discussion draws parallels between Cherenkov radiation and the refraction of light, emphasizing that both are governed by the phase velocity rather than the group velocity. The Mach cone analogy is also introduced to illustrate the relativistic aspects of light propagation in a medium.

PREREQUISITES
  • Understanding of phase velocity and group velocity in wave mechanics
  • Familiarity with the concept of refractive index (n)
  • Basic knowledge of Cherenkov radiation and its conditions
  • Awareness of Fermat's principle in optics
NEXT STEPS
  • Study the derivation of Cherenkov radiation using A. Sommerfeld's "Lectures on Theoretical Physics IV (Optics)"
  • Explore the mathematical formulation of phase velocity and group velocity
  • Investigate the relationship between Cherenkov radiation and the Mach cone in supersonic phenomena
  • Examine the implications of Cherenkov radiation in particle physics and astrophysics
USEFUL FOR

Physicists, optics researchers, and students studying wave phenomena, particularly those interested in the principles of Cherenkov radiation and its applications in various fields of physics.

JoePhysicsNut
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Why must the charged particle that leads to Cherenkov radiation travel faster than the phase velocity of light not the group velocity of light?

One of the sides of the triangle that is used to define cosθ is v=c/n i.e. the phase velocity. I don't see why it's one rather than the other.

Thanks!
 
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Cherenkov radiation happens when the phase of the light cannot "keep up" with the particle, so you cannot get a static field around the particle (as seen by the particle).

One of the sides of the triangle that is used to define cosθ is v=c/n i.e. the phase velocity. I don't see why it's one rather than the other.
It is very similar to refraction of light.
 
mfb said:
Cherenkov radiation happens when the phase of the light cannot "keep up" with the particle, so you cannot get a static field around the particle (as seen by the particle).

Thanks for the reply! But again, is there a qualitative way of understanding why it's phase velocity not group velocity?

mfb said:
It is very similar to refraction of light.

True, refraction of light is also controlled by c/n - the phase velocity. Refraction can be understood from Fermat's principle, but again I don't know why it's one type of speed rather than the other.
 
It's not so much similar to the refraction of light but rather to the Mach cone of supersonic sound, here of course for the relativistic case of light propagation in a medium. You find the full calculation of the Cherenkov-radiation field in

A. Sommerfeld, Lectures on Theoretical Physics IV (Optics)

These are pretty old but very marvelous textbooks on classical theoretical physics. I really love those :-).
 

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