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elduderino
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Not a Homework problem, but I think it belongs here.
Consider four dirac matrices that obey
M_i M_j + M_j M_i = 2 \delta_{ij} I
knowing the property that Tr ABC = Tr CAB = Tr BCA show that the matrices are traceless.
Tr MN = Tr NM
The square of each dirac matrix is a unit matrix according to the definition above. For i,j unequal
M_i M_j = - M_j M_i
Since these matrices are equal their traces should be equal
Tr M_i M_j = - Tr M_j M_i =- Tr M_i M_j
implying Tr M_i M_j = Tr M_j M_i = 0 for i \neq j
So far, I have not been able to prove that each of these dirac matrices individually as a vanishing trace. I tried
Tr M_i M_j = \sum_k \sum_r (M_i)_{kr}(M_j)_{rk} = 0
but can't conclude anything. This is embarrasing, as this seems pretty basic. Can someone help?
Homework Statement
Consider four dirac matrices that obey
M_i M_j + M_j M_i = 2 \delta_{ij} I
knowing the property that Tr ABC = Tr CAB = Tr BCA show that the matrices are traceless.
Homework Equations
Tr MN = Tr NM
The Attempt at a Solution
The square of each dirac matrix is a unit matrix according to the definition above. For i,j unequal
M_i M_j = - M_j M_i
Since these matrices are equal their traces should be equal
Tr M_i M_j = - Tr M_j M_i =- Tr M_i M_j
implying Tr M_i M_j = Tr M_j M_i = 0 for i \neq j
So far, I have not been able to prove that each of these dirac matrices individually as a vanishing trace. I tried
Tr M_i M_j = \sum_k \sum_r (M_i)_{kr}(M_j)_{rk} = 0
but can't conclude anything. This is embarrasing, as this seems pretty basic. Can someone help?
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