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NEW:
The real
valued and spatially symmetric
representation of the Dirac
equation
Understanding
Relativistic Quantum Field Theory
Hans de Vries (My book in progress)
Part
I Relativistic
foundations of light and matter Fields
Chapter 1:
Elementary solutions of the classical wave
equation
Chapter 2:
Lorentz
contraction from the classical wave
equation
Chapter
3: Time dilation from
the
classical wave equation
Chapter
4:
Non-simultaneity from the
classical wave equation
Part
II Advanced
treatment of the EM field
Chapter 5:
Relativistic formulation of
the electromagnetic field
Chapter 6:
The Chern-Simons EM spin
and axial current density
Chapter 7:
The EM stress energy tensor
and spin tensor
Chapter 8:
Advanced EM treatment of
Spin 1/2 fermions
Part
III The
relativistic matter wave equations
Chapter
9:
Relativistic
matter waves from Klein Gordon's
equation
Chapter
10:
Operators of the scalar Klein
Gordon field
Chapter
11:
EM Lorentz force derived from
Klein Gordon's equation
Chapter 12:
Klein Gordon transition currents and
virtual photons
Chapter
13:
Propagators of the real Klein
Gordon field
Chapter 14:
Propagators of the complex Klein Gordon
field
Chapter 15:
The self propagator of the Klein Gordon
field
Chapter 16:
The Poincare group
and relativistic wave functions
Chapter
17:
The Dirac
Equation
Chapter
18:
Transformations of the
bilinear fields of the Dirac
electron
Chapter
19: Gordon
decomposition of the vector/axial
currents
Chapter
20:
Operators
and Observables of the Dirac field
Chapter 21:
The EM
interactions with the Dirac field
Chapter
22: The Hamiltonian and
Lagrangian densities
Part IV
Foundations of Quantum
Electro Dynamics
Chapter 23:
Scattering and momentum
conservation
Chapter 24:
Decay rates
and Cross sections
Chapter 25: Interference currents
from transitions
Chapter 26:
Propagation from the interaction term
Chapter 27:
Feynman
rules and diagrams of QED
Chapter 28:
Elementary QED scattering
processes
Chapter 29:
Higher
order Feynman diagrams
Chapter 30:
Path integral methods
Part V Non
Abelian gauge theories
Chapter 31:
The Electroweak theory
Chapter 32:
The Electroweak interactions with
quarks
Chapter 33:
Quantum Chromo Dynamics
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