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The inclusion of fermions – J=1/2 particles

Published byCarmella Lyons Modified over 8 years ago

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Presentation on theme: "The inclusion of fermions – J=1/2 particles"— Presentation transcript:

1 The inclusion of fermions – J=1/2 particles
Weyl spinors Dirac spinor 2-component spinors of SU(2) velocity Left-handed m=0 Right-handed The spinor structure follows from the representation structure of the Lorentz Group …

2 The Lorentz transformations form a group, G
Rotations Angular momentum operator

3 } } The Lorentz group Generate the group SO(3,1)
To construct representations a more convenient (non-Hermitian) basis is }

4 } The Lorentz group Generate the group SO(3,1)
To construct representations a more convenient (non-Hermitian) basis is Representations

5 Weyl spinors Dirac spinor 2-component spinors of SU(2)
Rotations and Boosts Dirac spinor Can combine to form a 4-component “Dirac” spinor Lorentz transformations where Weyl basis

6 Weyl spinors Dirac spinor 2-component spinors of SU(2)
Rotations and Boosts Dirac spinor Can combine to form a 4-component “Dirac” spinor Lorentz transformations where (Dirac gamma matrices, …new 4-vector ) Note :

7 The Dirac equation Fermions described by 4-cpt Dirac spinors
Lorentz invariant New 4-vector The Lagrangian Dimension? From Euler Lagrange equation obtain the Dirac equation Feynman rules U(1) symmetry

8 Fermion masses Lorentz invariant Dirac mass Lorentz invariant
Only term allowed by charge conservation is Majorana mass

9 Fermions and the weak interactions
Fermi theory of decay

10 } V-A Fermions and the weak interactions Fermi theory of decay W+ p n

11 Weak Interactions Symmetry : Local conservation of
SU(2) local gauge theory Symmetry : Local conservation of 2 weak isospin charges Weak coupling, α2 u d Gauge boson (J=1) Wa=1..3 A non-Abelian (SU(2)) local gauge field theory e Neutral currents

12 Massive vector propagator (W, Z bosons)
Free particle solution Helicity polarisation vectors

13 } Propagation of unstable scalar particle No decay iJ iJ ..
Particle decays into final state n …. iJ Optical theorem – conservation of probability, time evolution is unitary }

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16 Fermi theory (‘40s) Dimensional analysis The hard part!

17 In μ decay

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20 Have Fun! Fundamental principles of particle physics
Introduction - Fundamental particles and interactions Symmetries I - Relativity Quantum field theory - Quantum Mechanics + relativity Theory confronts experiment - Cross sections and decay rates Symmetries II – Gauge symmetries, the Standard Model Fermions and the weak interactions The Standard Model and Beyond Have Fun!

21

22 velocity Left-handed m=0 Right-handed

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