Spin Angular Momentum Dirac Equation

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Discussion Overview

The discussion revolves around the nature of spin angular momentum in the context of the Dirac equation, exploring how the wave-function components relate to spin and orbital angular momentum. Participants examine the implications of the four-component wave-function and its relationship to spin states.

Discussion Character

  • Exploratory
  • Technical explanation
  • Conceptual clarification
  • Debate/contested

Main Points Raised

  • Some participants question whether each of the four components of the Dirac wave-function has a spin angular momentum of h-bar/2, suggesting that this view may be overly simplistic.
  • It is proposed that the spin operator mixes the components of the Dirac wave function, indicating that spin angular momentum is a property of all four components collectively rather than any single component.
  • There is a suggestion that if a particle is in a spin eigenstate, the phases of the components must be related, which is illustrated through the nonrelativistic limit of the Dirac equation, the Pauli equation.
  • A participant raises a question regarding whether h-bar or h-bar divided by 2 represents spin or orbital angular momentum, indicating uncertainty about the classification of angular momentum types.

Areas of Agreement / Disagreement

Participants do not reach a consensus on the nature of spin angular momentum in the Dirac equation, with multiple competing views and uncertainties remaining regarding the relationship between the wave-function components and angular momentum types.

Contextual Notes

The discussion includes assumptions about the properties of wave-functions and their components, as well as the implications of different angular momentum definitions, which remain unresolved.

Bob Dylan
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In the Dirac equation, the wave-function is broken into four wave-functions in four entries in a column of a matrix. Since there are four separate versions of the wave-function, does each version have the spin angular momentum of h-bar/2? This seems overly simplistic. How does spin angular momentum work for the Dirac equation?
 
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Bob Dylan said:
In the Dirac equation, the wave-function is broken into four wave-functions in four entries in a column of a matrix. Since there are four separate versions of the wave-function, does each version have the spin angular momentum of h-bar/2? This seems overly simplistic. How does spin angular momentum work for the Dirac equation?

The spin operator mixes the components of the Dirac wave function, so it's not a property of anyone component, but of all 4. On the other hand, orbital angular momentum does not mix the components, so it makes sense to say that a single component has an orbital angular momentum, but not to say that it has spin angular momentum.
 
Does this mean all four components share the same phase?
 
Bob Dylan said:
Does this mean all four components share the same phase?

If a particle is in a spin eigenstate, then the phases of the components must be related.

It's easiest to see with the two-component nonrelativistic limit of the Dirac equation, the Pauli equation.

With the Pauli equation, the wave function has two components: ##\psi = \left( \begin{array} \\ \alpha \\ \beta \end{array} \right)##.

If ##\psi## is spin-up in the z-direction, that means ##\left( \begin{array} \\ 1 & 0 \\ 0 & -1 \end{array} \right)
\left( \begin{array} \\ \alpha \\ \beta \end{array} \right) = +1 \left( \begin{array} \\ \alpha \\ \beta \end{array} \right)##. That implies ##\beta = 0##.

If ##\psi## is spin-up in the x-direction, that means ##\left( \begin{array} \\ 0 & 1 \\ 1 & 0 \end{array} \right)
\left( \begin{array} \\ \alpha \\ \beta \end{array} \right) = +1 \left( \begin{array} \\ \alpha \\ \beta \end{array} \right)##. That implies ##\alpha = \beta##.
 
So is h-bar (or h-bar divided by 2) a form of spin or orbital angular momentum?
 

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