Wigner's 6-j symbols were introduced by Eugene Paul Wigner in 1940 and published in 1965. They are defined as a sum over products of four Wigner 3-j symbols,
\begin{Bmatrix} j1&j2&j3\\ j4&j5&j6 \end{Bmatrix} =
| \sum | |
| m1,...,m6 |
| ||||||||||
| (-1) |
\begin{pmatrix} j1&j2&j3\\ -m1&-m2&-m3 \end{pmatrix} \begin{pmatrix} j1&j5&j6\\ m1&-m5&m6 \end{pmatrix} \begin{pmatrix} j4&j2&j6\\ m4&m2&-m6 \end{pmatrix} \begin{pmatrix} j4&j5&j3\\ -m4&m5&m3 \end{pmatrix} .
They are closely related to the Racah W-coefficients, which are used for recoupling 3 angular momenta, although Wigner 6-j symbols have higher symmetry and therefore provide a more efficient means of storing the recoupling coefficients.[1] Their relationship is given by:
\begin{Bmatrix} j1&j2&j3\\ j4&j5&j6 \end{Bmatrix} =
| j1+j2+j4+j5 | |
| (-1) |
W(j1j2j5j4;j3j6).
The 6-j symbol is invariant under any permutation of the columns:
\begin{Bmatrix} j1&j2&j3\\ j4&j5&j6 \end{Bmatrix} = \begin{Bmatrix} j2&j1&j3\\ j5&j4&j6 \end{Bmatrix} = \begin{Bmatrix} j1&j3&j2\\ j4&j6&j5 \end{Bmatrix} = \begin{Bmatrix} j3&j2&j1\\ j6&j5&j4 \end{Bmatrix} = …
\begin{Bmatrix} j1&j2&j3\\ j4&j5&j6 \end{Bmatrix} = \begin{Bmatrix} j4&j5&j3\\ j1&j2&j6 \end{Bmatrix} = \begin{Bmatrix} j1&j5&j6\\ j4&j2&j3 \end{Bmatrix} = \begin{Bmatrix} j4&j2&j6\\ j1&j5&j3 \end{Bmatrix}.
The 6-j symbol
\begin{Bmatrix} j1&j2&j3\\ j4&j5&j6 \end{Bmatrix}
j1=|j2-j3|,\ldots,j2+j3
When j6 = 0 the expression for the 6-j symbol is:
\begin{Bmatrix} j1&j2&j3\\ j4&j5&0 \end{Bmatrix} =
| |||||||||||
| \sqrt{(2j1+1)(2j2+1) |
The 6-j symbols satisfy this orthogonality relation:
| \sum | |
| j3 |
(2j3+1) \begin{Bmatrix} j1&j2&j3\\ j4&j5&j6 \end{Bmatrix} \begin{Bmatrix} j1&j2&j3\\ j4&j5&j6' \end{Bmatrix} =
| ||||||||||||||
| 2j6+1 |
\begin{Bmatrix}j1&j5&j6\end{Bmatrix}\begin{Bmatrix}j4&j2&j6\end{Bmatrix}.
A remarkable formula for the asymptotic behavior of the 6-j symbol was first conjectured by Ponzano and Regge[2] and later proven by Roberts.[3] The asymptotic formula applies when all six quantum numbers j1, ..., j6 are taken to be large and associates to the 6-j symbol the geometry of a tetrahedron. If the 6-j symbol is determined by the quantum numbers j1, ..., j6 the associated tetrahedron has edge lengths Ji = ji+1/2 (i=1,...,6) and the asymptotic formula is given by,
\begin{Bmatrix} j1&j2&j3\\ j4&j5&j6 \end{Bmatrix} \sim
| 1 | |
| \sqrt{12\pi|V| |
In representation theory, 6-j symbols are matrix coefficients of the associator isomorphism in a tensor category.[4] For example, if we are given three representations Vi, Vj, Vk of a group (or quantum group), one has a natural isomorphism
(Vi ⊗ Vj) ⊗ Vk\toVi ⊗ (Vj ⊗ Vk)
When a monoidal category is semisimple, we can restrict our attention to irreducible objects, and define multiplicity spaces
| \ell | |
| H | |
| i,j |
=\operatorname{Hom}(V\ell,Vi ⊗ Vj)
Vi ⊗ Vj=oplus\ell
| \ell | |
| H | |
| i,j |
⊗ V\ell
(Vi ⊗ Vj) ⊗ Vk\congoplus\ell,m
| \ell | |
| H | |
| i,j |
⊗
| m | |
| H | |
| \ell,k |
⊗ Vm while Vi ⊗ (Vj ⊗ Vk)\congoplusm,n
| m | |
| H | |
| i,n |
⊗
| n | |
| H | |
| j,k |
⊗ Vm
| k,m | |
| \Phi | |
| i,j |
:oplus\ell
| \ell | |
| H | |
| i,j |
⊗
| m | |
| H | |
| \ell,k |
\tooplusn
| m | |
| H | |
| i,n |
⊗
| n | |
| H | |
| j,k |
\begin{Bmatrix} i&j&\ell\\ k&m&n \end{Bmatrix} =
| k,m | |
| (\Phi | |
| i,j |
)\ell,n
In abstract terms, the 6-j symbols are precisely the information that is lost when passing from a semisimple monoidal category to its Grothendieck ring, since one can reconstruct a monoidal structure using the associator. For the case of representations of a finite group, it is well known that the character table alone (which determines the underlying abelian category and the Grothendieck ring structure) does not determine a group up to isomorphism, while the symmetric monoidal category structure does, by Tannaka-Krein duality. In particular, the two nonabelian groups of order 8 have equivalent abelian categories of representations and isomorphic Grothdendieck rings, but the 6-j symbols of their representation categories are distinct, meaning their representation categories are inequivalent as monoidal categories. Thus, the 6-j symbols give an intermediate level of information, that in fact uniquely determines the groups in many cases, such as when the group is odd order or simple.[5]
. Biedenharn . L. C. . Lawrence Biedenharn . van Dam . H. . Quantum Theory of Angular Momentum: A collection of Reprints and Original Papers . 1965 . . 0-12-096056-7.
. Albert Messiah . Quantum Mechanics . II . 1981 . 12th . . 0-7204-0045-7.