Finding Eigenvalues of Dirac Matrices with Constraint Conditions

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waht
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I'm stuck on a problem. Given a Hamiltonian

[tex]H_{ab} = cP_j(\alpha^{j})_{ab} + mc^{2} (\beta)_{ab} [/itex]<br /> <br /> then<br /> <br /> [tex](H^{2})_{ab} = (\textbf{P}^{2}c^{2} + m^{2}c^{4}) \delta_{ab} [/itex]<br /> <br /> holds if<br /> <br /> [tex]\left\{\alpha^j,\alpha^k}\right\}_{ab} = 2 \delta^{jk} \delta_{ab} [/itex]<br /> <br /> [tex]\left\{\alpha^j, \beta \right\}_{ab} = 0 [/itex]<br /> <br /> [tex]\delta_{ab} = (\beta^2)_{ab} [/itex]<br /> <br /> I'd like to show that [itex]Tr (\alpha) = 0[/itex] and [itex]Tr( \beta) = 0[/itex]<br /> <br /> My plan is to find the eigenvalues of alpha and beta and add them up. But how could I find the eigenvalues using the constraint conditions?[/tex][/tex][/tex][/tex][/tex]
 
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you missed one crucial equation,
[tex]\alpha_i^2=1[/tex]

a clever use of
[tex]\alpha_i^2=\beta^2=1[/tex]
and the anti-commutation relation should give you the answer.

also, note that if A,B,C are matrices
[tex]Tr(ABC)=Tr(CAB)=Tr(BCA)[/tex]

(edit) nevermind using the eigenvalues, i was thinking that those are 2D matrices; their dimensions are not given in this case.
 
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So would

[tex]Tr(\alpha) = Tr(\alpha\, (\alpha^j)^2 \,\beta^2) [/itex][/tex]