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Chapter II Klein Gordan Field Lecture 5.

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1 Chapter II Klein Gordan Field Lecture 5

2 Charge operator We consider the internal symmetry Transformations ----(1) Above tranformation will not change space- Time coordinates.

3 Infinitesimally, we can write
--(2) Infinitesimal constant parameter

4 Lagrangian does not change under above
symmetry transformations i.e., -----(3)

5 Recall the following from Noether theorem
Whenever the Lagrangian density is invariant It leads to conserved current Where For internal symmetry

6 We can write for complex Klein Gordon field
= ----(5)

7 Parameter independent current
----(7) Which is a vector current and is conserved ----(8)

8 Conserved charge -----(9) Normal ordered charge operator ---(10)

9 Charge operator is associated with the global
phase transformation similar to electromagnetic Interactions (U(1) phase transformation). Above charge operator is identified as electric Charge. Note, using (10), ----(12) Vacuum does not carry any charge.

10 Acting on 1st of the one particle state, we get
----(13) Thus is eigenstate with eigenvalue +1

11 Acting on 2nd of the one particle state, we get
----(14) Thus is eigenstate with eigenvalue -1

12 Complex Klein Gordon field describe the
particles carrying charge and have spin 0. Real Klein Gordon field is for neutral spin 0 Particles. Hamiltonian Is invariant under This is called charge conjugation property

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