Non-diagonality of Dirac's Hamiltonian

Mesmerized · Aug 18, 2011

Hi all,

My question is why Dirac's Hamiltonian isn't diagonal? As much as I understand, the momentum of the particle and it's spin belong to the complete set of commuting variables, which define the state of the particle, and their eigenstates must also be energy eigenstates. But because Hamiltonian is non-diagonal (because gamma matrices are not diagonal), it follows that if we have a particle with definite momentum and definite spin, with time it is going to change it's state to become a particle with no definite spin.

Where am I wrong?

dextercioby · Aug 18, 2011

The spin vector operator is no constant of motion (doesn't commute with the Hamiltonian, which is time-independent) for the Dirac' Hamiltonian, but [tex] \vec{S} \cdot \vec{P} [/tex] is.

Mesmerized · Aug 18, 2011

thanks, don't know why it's not written in the textbook, and I made a wrong assumption

Non-diagonality of Dirac's Hamiltonian

Related to Non-diagonality of Dirac's Hamiltonian

1. What is the significance of the non-diagonality of Dirac's Hamiltonian?

2. How does the non-diagonality of Dirac's Hamiltonian affect the energy levels of a particle?

3. Can the non-diagonality of Dirac's Hamiltonian be applied to all particles?

4. How does the non-diagonality of Dirac's Hamiltonian impact our understanding of quantum mechanics?

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