- #1
SgrA*
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Hello,
Here's a textbook question and my solution, please check if it is correct, I'm slightly doubtful about the second part.
Consider Hermitian matrices M_1, M_2, M_3,\ and\ M_4 that obey:
M_i M_j+M_j M_i = 2 \delta_{ij} I \hspace{10mm} for\ i,\ j\ = 1,\ ... ,4
(1) Show that the eigenvalues of M_i are ±1.
Solution: When i = j, \hspace{20mm} M_i M_i = I.
Since M_i are Hermitian, this equation implies that they are unitary. The eigenvalues of a unitary matrix are complex numbers of unit modulus, since it's also Hermitian, they have to be real. So, the eigenvalues have to be ±1. \hspace{20mm} Q.E.D.
(2) Show that M_i are traceless.
Solution: When i ≠ j, \\<br /> M_i M_j = -M_j M_i\\<br /> \Rightarrow M_i M_j M_i = -M_j M_i M_i\\<br /> \Rightarrow M_i M_j M_i = -M_j I\\<br /> \Rightarrow Tr(M_i M_j M_i) = -Tr(M_j) \\<br /> \Rightarrow Tr(M_j M_i M_i) = -Tr(M_j)\\<br /> \Rightarrow Tr(M_j) = -Tr(M_j)\\<br /> \Rightarrow Tr(M_j) = 0. \hspace{20mm} Q.E.D.
(3) Show that M_i cannot be odd-dimensional matrices.
Solution: For some eigenbasis U, D = U^†M_iU, D is a diagonal matrix with Tr(D) = Tr(M_i) and the diagonal elements of D are the eigenvalues, ±1. Also, Tr(D) = Tr(M_i) = 0. An odd dimension cannot result in a traceless matrix, hence by argument of parity, M_i are even dimensional matrices. \hspace{20mm}Q.E.D.
Thanks!
Here's a textbook question and my solution, please check if it is correct, I'm slightly doubtful about the second part.
Consider Hermitian matrices M_1, M_2, M_3,\ and\ M_4 that obey:
M_i M_j+M_j M_i = 2 \delta_{ij} I \hspace{10mm} for\ i,\ j\ = 1,\ ... ,4
(1) Show that the eigenvalues of M_i are ±1.
Solution: When i = j, \hspace{20mm} M_i M_i = I.
Since M_i are Hermitian, this equation implies that they are unitary. The eigenvalues of a unitary matrix are complex numbers of unit modulus, since it's also Hermitian, they have to be real. So, the eigenvalues have to be ±1. \hspace{20mm} Q.E.D.
(2) Show that M_i are traceless.
Solution: When i ≠ j, \\<br /> M_i M_j = -M_j M_i\\<br /> \Rightarrow M_i M_j M_i = -M_j M_i M_i\\<br /> \Rightarrow M_i M_j M_i = -M_j I\\<br /> \Rightarrow Tr(M_i M_j M_i) = -Tr(M_j) \\<br /> \Rightarrow Tr(M_j M_i M_i) = -Tr(M_j)\\<br /> \Rightarrow Tr(M_j) = -Tr(M_j)\\<br /> \Rightarrow Tr(M_j) = 0. \hspace{20mm} Q.E.D.
(3) Show that M_i cannot be odd-dimensional matrices.
Solution: For some eigenbasis U, D = U^†M_iU, D is a diagonal matrix with Tr(D) = Tr(M_i) and the diagonal elements of D are the eigenvalues, ±1. Also, Tr(D) = Tr(M_i) = 0. An odd dimension cannot result in a traceless matrix, hence by argument of parity, M_i are even dimensional matrices. \hspace{20mm}Q.E.D.
Thanks!
