Why don't scalar fields propagate superluminally?

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SUMMARY

The discussion centers on the propagation of scalar fields governed by the Klein-Gordon equation, specifically the equation \(\partial_t^2 \phi + (k^2 + m^2)\phi = 0\). It is established that while the phase velocity can exceed the speed of light, the group velocity, calculated as \(\frac{\partial \omega_k}{\partial k} = \frac{1}{\sqrt{1 + m^2/k^2}}\), remains subluminal for non-zero mass \(m\). This indicates that superluminal propagation is a misconception, as only massless fields can achieve a group velocity of 1, consistent with relativistic constraints.

PREREQUISITES
  • Understanding of the Klein-Gordon equation
  • Familiarity with concepts of phase and group velocity
  • Basic knowledge of relativistic field theory
  • Mathematical proficiency in calculus and differential equations
NEXT STEPS
  • Study the implications of the Klein-Gordon equation in quantum field theory
  • Learn about the differences between phase velocity and group velocity
  • Explore the concept of superluminal signals in theoretical physics
  • Investigate massless fields and their behavior under relativistic conditions
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The discussion is beneficial for theoretical physicists, students of quantum field theory, and anyone interested in the properties of scalar fields and their propagation characteristics in relativistic frameworks.

ramparts
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This is a really basic question, but...

Say I have a massive scalar field obeying the Klein-Gordon equation linearized about flat space,

\partial_t^2 \phi + (k^2 + m^2)\phi = 0.

This has solutions

\phi \sim e^{\pm \sqrt{k^2 + m^2}t}

and the sound speed should be

\omega_k/k = \sqrt{1 + m^2/k^2} \geq 1.

in which case perturbations of the scalar field propagate superluminally at all scales. This is clearly wrong, but why?
 
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I think it's the group velocity that shouldn't be superluminal. The group velocity is

##\frac{\partial w_k}{\partial k} = \frac{2k}{2 \sqrt{k^2 + m^2}} = \frac{1}{\sqrt{1 + m^2/k^2}} < 1 ##

unless ##m = 0## in which case the group velocity is 1, as it should be.
 
Of course. Thanks a lot!
 

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