Manipulation with the Dirac equation

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spaghetti3451
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I know that the Dirac equation is ##i\gamma^{\mu}\partial_{\mu}\psi=m\psi##.

How do I use this to show that ##(\partial_{\mu}\bar{\psi})\gamma^{\mu}=im\bar{\psi}##?
 
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First of all you have (in the usual standard representations of the Dirac matrices)
$$\gamma^{\mu \dagger}=\gamma^0 \gamma^{\mu} \gamma^0,$$
the "pseudo-hermitecity relation" and the definition
$$\overline{\psi}=\psi^{\dagger} \gamma^0.$$
So now take the Dirac equation and first apply Hermitean conjugation:
$$-\mathrm{i} \partial_{\mu} \psi^{\dagger} \gamma^{\mu \dagger}=m\psi^{\dagger}.$$
Now use ##(\gamma^0)^2=1## to first write on the left-hand side
$$-\mathrm{i} \partial_{\mu} \overline{\psi} \gamma^0 \gamma^{\mu \dagger} = m \psi^{\dagger}.$$
Finally multiply this equation with ##\gamma^0## and use the pseudo-hermitecity relation of the Dirac matrices to finally get the claimed equation:
$$-\mathrm{i} \partial_{\mu} \overline{\psi} \gamma^{\mu}=m \overline{\psi}.$$
 
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Well, the Dirac equation in line 1 is one of the two Euler-Lagrange equations for the symmetrized Lagrangian density. The other Euler-Lagrange equation is the one whose derivation he sought. Your solution is direct, I was trying to lead him there.
 
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