The Effective Lagrangian of the Electromagnetic Field

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SUMMARY

The effective Lagrangian of the electromagnetic field is defined as L=(1/8pi) (E^2-B^2) in Gaussian units. This expression represents the normal Lagrangian density of the electromagnetic field, which is derived from a thorough analysis of the unitary representations of the Poincaré group. It is the sole Lagrangian for a free massless vector field with discrete intrinsic helicity degrees of freedom and parity invariance, realizable through an Abelian gauge theory. For further details, refer to the provided resource.

PREREQUISITES
  • Understanding of Lagrangian mechanics
  • Familiarity with electromagnetic field theory
  • Knowledge of Poincaré group representations
  • Concept of Abelian gauge theories
NEXT STEPS
  • Study the derivation of the Lagrangian density for electromagnetic fields
  • Explore the implications of parity invariance in field theories
  • Learn about unitary representations of the Poincaré group
  • Investigate Abelian gauge theory applications in physics
USEFUL FOR

Physicists, particularly those specializing in theoretical physics, field theory, and anyone interested in the mathematical foundations of electromagnetic interactions.

r.sahebi
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hi to everyone

L=T-V
as you know it is the lagrangian equation
the effective Lagrangian of the electromagnetic field is given by following relation in gaussian units.
L=(1/8pi) (E^2-B^2)
how is must calculate this relation?

(the energy density of electromagnetic fields is given by u=(1/8pi) (E^2+B^2) )
 
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I don't know why you'd call that 'effective', that is the normal lagrangian density of the e-m field (without gauge fixing, of course).
 
dextercioby said:
I don't know why you'd call that 'effective', that is the normal lagrangian density of the e-m field (without gauge fixing, of course).

yes, that's my wrong
can you tell me how i can have it?
 
This comes out from a careful analysis of the unitary representations of the Poincare group. This Lagrangian is the only one for a free massless vector field (written in its representation as a four-vector field) with only discrete intrinsic (helicity) degrees of freedom and admitting space-inversion symmetry (parity invariance). This can only be realized in terms of an Abelian gauge theory. For details, see

http://fias.uni-frankfurt.de/~hees/publ/lect.pdf

(Appendix B).
 
vanhees71 said:
This comes out from a careful analysis of the unitary representations of the Poincare group. This Lagrangian is the only one for a free massless vector field (written in its representation as a four-vector field) with only discrete intrinsic (helicity) degrees of freedom and admitting space-inversion symmetry (parity invariance). This can only be realized in terms of an Abelian gauge theory. For details, see

http://fias.uni-frankfurt.de/~hees/publ/lect.pdf

(Appendix B).

thanks a lot.
 

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