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Fermions and the Dirac Equation In 1928 Dirac proposed the following form for the electron wave equation: The four  µ matrices form a Lorentz 4-vector,

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Presentation on theme: "Fermions and the Dirac Equation In 1928 Dirac proposed the following form for the electron wave equation: The four  µ matrices form a Lorentz 4-vector,"— Presentation transcript:

1 Fermions and the Dirac Equation In 1928 Dirac proposed the following form for the electron wave equation: The four  µ matrices form a Lorentz 4-vector, with components, µ. That is, they transform like a 4-vector under Lorentz transformations between moving frames. Each  µ is a 4x4 matrix. 4x4 matrix4x4 unit matrix 4-row column matrix

2 Dirac wanted an equation with only first order derivatives: But the above must satisfy the Klein=Gordon equation:

3 This must = Klein-Gordon equation 10 conditions must be satisfies

4 Pauli spinors:  =  1 =  2 =  3 = They must be 4x4 matrices!

5 The 0 and 1,2,3 matrices anti-commute The 1,2,3, matrices anti-commute with each other The square of the 1,2,3, matrices equal minus the unit matrix The square of the 0 matrix equals the unit matrix 4x4 unit matrix All of the above can be summarized in the following expression: Here g µ  is not a matrix, it is a component of the inverse metric tensor. 4x4 matrices

6 With the above properties for the  matrices one can show that if  satisfies the Dirac equation, it also satisfies the Klein Gordon equation. It takes some work. 4 component column matrix 4x4 unit matrix Klein-Gordon equation: Dirac derived the properties of the  matrices by requiring that the solution to the Dirac equation also be a solution to the Klein-Gordon equation. In the process it became clear that the  matrices had dimension 4x4 and that the  was a column matrix with 4 rows.

7 The Dirac equation in full matrix form 00 11 22 33 spin dependence space-time dependence

8 p0p0 After taking partial derivatives … note 2x2 blocks.

9 Writing the above as a 2x2 (each block of which is also 2x2)

10 Incorporate the p and E into the matrices …

11 The exponential (non-zero) can be cancelled out.

12 Finally, we have the relationships between the upper and lower spinor components

13

14 p along z and spin = +1/2 p along z and spin = -1/2 Spinors for the particle with p along z direction

15 p along z and spin = +1/2 p along z and spin = -1/2 Spinors for the anti-particle with p along z direction

16 Field operator for the spin ½ fermion Spinor for antiparticle with momentum p and spin s Creates antiparticle with momentum p and spin s Note: p µ p µ = m 2 c 2

17 Creates particle with momentum p and spin s r, s =  1/2

18 Lagrangian Density for Spin 1/2 Fermions 1. This Lagrangian density is used for all the quarks and leptons – only the masses will be different! 2. The Euler Lagrange equations, when applied to this Lagrangian density, give the Dirac Equation! Comments: 3. Note that L is a Lorentz scalar.

19 Dirac equation The Euler – Lagrange equations applied to L: [ A B ] † = B † A †

20 Lagrangian Density for Spin 1/2 Quarks and Leptons Now we are ready to talk about the gauge invariance that leads to the Standard Model and all its interactions. Remember a “gauge invariance” is the invariance of the above Lagrangian under transformations like   e i  . The physics is in the  -- which can be a matrix operator and depend on x,y, z and t.

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