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Matrices of the form: $$\begin{pmatrix} iz+iy&-iz+w&-iy-w\\ -iz-w&iz+ix&-ix+w\\ -iy+w&-ix-w&iy+ix\end{pmatrix}$$ where $x,y,z,w$ may be assumed to be real, form a Lie algebra. That is, such matrices are closed under addition and multiplication, and include inverses, zero, and unity. Each row or column sums to zero. Can the exponentiation of this matrix be put into closed form?

That is, can we solve: $$\begin{pmatrix} u_{11}&u_{12}&u_{13}\\ u_{21}&u_{22}&u_{23}\\ u_{31}&u_{32}&u_{33}\end{pmatrix} = \exp \begin{pmatrix} iz+iy&-iz+w&-iy-w\\ -iz-w&iz+ix&-ix+w\\ -iy+w&-ix-w&iy+ix\end{pmatrix}$$ in closed form for all the $u_{jk}$?

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    Do you have a meaningful description of that algebra?2011-04-06
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    Looks complicated. I can only think about diagonalizing $M$ and then exponentiating. Note that $M$ has one 0 eigenvalue...2011-04-06
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    @Mariano; It's obviously isomorphic (or whatever the word mathematicians use) to u(2), i.e. the Hermitian 2x2 matrices. Note that there's a difference in how math and physics define these things so I could be off by a factor of $i$.2011-04-06
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    If it were *obviously* isomorphic to that, I would not have asked... In any case, if you know it is you should probably add that information to the question.2011-04-07
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    @Mariano; To show equivalence to u(2), use a Householder transformation, i.e. $u\to HuH^{-1}$ where H is a Householder matrix that block diagonalizes the above matrices. Sorry, that's an abuse of "obvious".2011-04-08

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