Clebsch–Gordan coefficients for SU(3)

In mathematical physics, Clebsch–Gordan coefficients are the expansion coefficients of total angular momentum eigenstates in an uncoupled tensor product basis. Mathematically, they specify the decomposition of the tensor product of two irreducible representations into a direct sum of irreducible representations, where the type and the multiplicities of these irreducible representations are known abstractly. The name derives from the German mathematicians Alfred Clebsch (1833–1872) and Paul Gordan (1837–1912), who encountered an equivalent problem in invariant theory.

Generalization to SU(3) of Clebsch–Gordan coefficients is useful because of their utility in characterizing hadronic decays, where a flavor-SU(3) symmetry exists (the eightfold way) that connects the three light quarks: up, down, and strange.

SU(3) group

edit

The special unitary group SU is the group of unitary matrices whose determinant is equal to 1.[1] This set is closed under matrix multiplication. All transformations characterized by the special unitary group leave norms unchanged. The SU(3) symmetry appears in the light quark flavour symmetry (among up, down, and strange quarks) dubbed the Eightfold Way (physics). The same group acts in quantum chromodynamics on the colour quantum numbers of the quarks that form the fundamental (triplet) representation of the group.

The group SU(3) is a subgroup of group U(3), the group of all 3×3 unitary matrices. The unitarity condition imposes nine constraint relations on the total 18 degrees of freedom of a 3×3 complex matrix. Thus, the dimension of the U(3) group is 9. Furthermore, multiplying a U by a phase, e leaves the norm invariant. Thus U(3) can be decomposed into a direct product U(1) × SU(3)/Z3. Because of this additional constraint, SU(3) has dimension 8.

Generators of the Lie algebra

edit

Every unitary matrix U can be written in the form

 

where H is hermitian. The elements of SU(3) can be expressed as

 

where   are the 8 linearly independent matrices forming the basis of the Lie algebra of SU(3), in the triplet representation. The unit determinant condition requires the   matrices to be traceless, since

 .

An explicit basis in the fundamental, 3, representation can be constructed in analogy to the Pauli matrix algebra of the spin operators. It consists of the Gell-Mann matrices,

 

These are the generators of the SU(3) group in the triplet representation, and they are normalized as

 

The Lie algebra structure constants of the group are given by the commutators of  

 

where   are the structure constants completely antisymmetric and are analogous to the Levi-Civita symbol   of SU(2).

In general, they vanish, unless they contain an odd number of indices from the set {2,5,7}, corresponding to the antisymmetric λs. Note  .

Moreover,

 

where   are the completely symmetric coefficient constants. They vanish if the number of indices from the set {2, 5, 7} is odd. In terms of the matrices,

 

Standard basis

edit
 
Root system of SU(3). The 6 roots are mutually inclined by π/3 to form a hexagonal lattice: α corresponds to isospin; β to U-spin; and α β to V-spin.

A slightly differently normalized standard basis consists of the F-spin operators, which are defined as   for the 3, and are utilized to apply to any representation of this algebra.

The Cartan–Weyl basis of the Lie algebra of SU(3) is obtained by another change of basis, where one defines,[2]

 
 
 
 
 

Because of the factors of i in these formulas, this is technically a basis for the complexification of the su(3) Lie algebra, namely sl(3,C). The preceding basis is then essentially the same one used in Hall's book.[3]

Commutation algebra of the generators

edit

The standard form of generators of the SU(3) group satisfies the commutation relations given below,

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

All other commutation relations follow from hermitian conjugation of these operators.

These commutation relations can be used to construct the irreducible representations of the SU(3) group.

The representations of the group lie in the 2-dimensional I3Y plane. Here,   stands for the z-component of Isospin and   is the Hypercharge, and they comprise the (abelian) Cartan subalgebra of the full Lie algebra. The maximum number of mutually commuting generators of a Lie algebra is called its rank: SU(3) has rank 2. The remaining 6 generators, the ± ladder operators, correspond to the 6 roots arranged on the 2-dimensional hexagonal lattice of the figure.

Casimir operators

edit

The Casimir operator is an operator that commutes with all the generators of the Lie group. In the case of SU(2), the quadratic operator J2 is the only independent such operator.

In the case of SU(3) group, by contrast, two independent Casimir operators can be constructed, a quadratic and a cubic: they are,[4]

 

These Casimir operators serve to label the irreducible representations of the Lie group algebra SU(3), because all states in a given representation assume the same value for each Casimir operator, which serves as the identity in a space with the dimension of that representation. This is because states in a given representation are connected by the action of the generators of the Lie algebra, and all generators commute with the Casimir operators.

For example, for the triplet representation, D(1,0), the eigenvalue of   is 4/3, and of  , 10/9.

More generally, from Freudenthal's formula, for generic D(p,q), the eigenvalue[5] of   is

 .

The eigenvalue ("anomaly coefficient") of   is[6]

 

It is an odd function under the interchange pq. Consequently, it vanishes for real representations p = q, such as the adjoint, D(1,1), i.e. both   and anomalies vanish for it.

Representations of the SU(3) group

edit

The irreducible representations of SU(3) are analyzed in various places, including Hall's book.[7] Since the SU(3) group is simply connected,[8] the representations are in one-to-one correspondence with the representations of its Lie algebra[9] su(3), or the complexification[10] of its Lie algebra, sl(3,C).

We label the representations as D(p,q), with p and q being non-negative integers, where in physical terms, p is the number of quarks and q is the number of antiquarks. Mathematically, the representation D(p,q) may be constructed by tensoring together p copies of the standard 3-dimensional representation and q copies of the dual of the standard representation, and then extracting an irreducible invariant subspace.[11] (See also the section of Young tableaux below: p is the number of single-box columns, "quarks", and q the number of double-box columns, "antiquarks").

Still another way to think about the parameters p and q is as the maximum eigenvalues of the diagonal matrices

 .

(The elements   and   are linear combinations of the elements   and  , but normalized so that the eigenvalues of   and   are integers.) This is to be compared to the representation theory of SU(2), where the irreducible representations are labeled by the maximum eigenvalue of a single element, h.

The representations have dimension[12]

 
The 10 representation D(3,0) (spin 3/2 baryon decuplet)
 

their irreducible characters are given by[13]

 

and the corresponding Haar measure is[13]   such that   and  ,

 

An SU(3) multiplet may be completely specified by five labels, two of which, the eigenvalues of the two Casimirs, are common to all members of the multiplet. This generalizes the mere two labels for SU(2) multiplets, namely the eigenvalues of its quadratic Casimir and of I3.

Since  , we can label different states by the eigenvalues of   and   operators,  , for a given eigenvalue of the isospin Casimir. The action of operators on this states are,[14]

 
 
The representation of generators of the SU(3) group.
 
 
 
 
 
 

Here,

 

and

 
 
The 15-dimensional representation D(2,1)

All the other states of the representation can be constructed by the successive application of the ladder operators   and   and by identifying the base states which are annihilated by the action of the lowering operators. These operators can be pictured as arrows whose endpoints form the vertices of a hexagon (picture for generators above).

Clebsch–Gordan coefficient for SU(3)

edit

The product representation of two irreducible representations   and   is generally reducible. Symbolically,

 

where   is an integer.

For example, two octets (adjoints) compose to

 

that is, their product reduces to an icosaseptet (27), decuplet, two octets, an antidecuplet, and a singlet, 64 states in all.

The right-hand series is called the Clebsch–Gordan series. It implies that the representation   appears   times in the reduction of this direct product of   with  .

Now a complete set of operators is needed to specify uniquely the states of each irreducible representation inside the one just reduced. The complete set of commuting operators in the case of the irreducible representation   is

 

where

 .

The states of the above direct product representation are thus completely represented by the set of operators

 

where the number in the parentheses designates the representation on which the operator acts.

An alternate set of commuting operators can be found for the direct product representation, if one considers the following set of operators,[15]

 

Thus, the set of commuting operators includes

 

This is a set of nine operators only. But the set must contain ten operators to define all the states of the direct product representation uniquely. To find the last operator Γ, one must look outside the group. It is necessary to distinguish different   for similar values of P and Q.

 

Thus, any state in the direct product representation can be represented by the ket,

 

also using the second complete set of commuting operator, we can define the states in the direct product representation as

 

We can drop the   from the state and label the states as

 

using the operators from the first set, and,

 

using the operators from the second set.

Both these states span the direct product representation and any states in the representation can be labeled by suitable choice of the eigenvalues.

Using the completeness relation,

 

Here, the coefficients

 

are the Clebsch–Gordan coefficients.

A different notation

edit

To avoid confusion, the eigenvalues   can be simultaneously denoted by μ and the eigenvalues   are simultaneously denoted by ν. Then the eigenstate of the direct product representation   can be denoted by[15]

 

where   is the eigenvalues of   and   is the eigenvalues of   denoted simultaneously. Here, the quantity expressed by the parenthesis is the Wigner 3-j symbol.

Furthermore,   are considered to be the basis states of   and   are the basis states of  . Also   are the basis states of the product representation. Here   represents the combined eigenvalues   and   respectively.

Thus the unitary transformations that connects the two bases are

 

This is a comparatively compact notation. Here,

 

are the Clebsch–Gordan coefficients.

Orthogonality relations

edit

The Clebsch–Gordan coefficients form a real orthogonal matrix. Therefore,

 

Also, they follow the following orthogonality relations,

 
 

Symmetry properties

edit

If an irreducible representation   appears in the Clebsch–Gordan series of  , then it must appear in the Clebsch–Gordan series of  . Which implies,

 

Where  
Since the Clebsch–Gordan coefficients are all real, the following symmetry property can be deduced,

 

Where  .

Symmetry group of the 3D oscillator Hamiltonian operator

edit

A three-dimensional harmonic oscillator is described by the Hamiltonian

 

where the spring constant, the mass and the Planck constant have been absorbed into the definition of the variables, ħ = m =1.

It is seen that this Hamiltonian is symmetric under coordinate transformations that preserve the value of  . Thus, any operators in the group SO(3) keep this Hamiltonian invariant.

More significantly, since the Hamiltonian is Hermitian, it further remains invariant under operation by elements of the much larger SU(3) group.

Proof that the symmetry group of linear isotropic 3D harmonic oscillator is SU(3)[16]

A symmetric (dyadic) tensor operator analogous to the Laplace–Runge–Lenz vector for the Kepler problem may be defined,

 

which commutes with the Hamiltonian,

 

Since it commutes with the Hamiltonian (its trace), it represents 6−1=5 constants of motion.

It has the following properties,

 
 
 

Apart from the tensorial trace of the operator , which is the Hamiltonian, the remaining 5 operators can be rearranged into their spherical component form as

 
 
 

Further, the angular momentum operators are written in spherical component form as

 
 

They obey the following commutation relations,

 
 
 
 
 
 

The eight operators (consisting of the 5 operators derived from the traceless symmetric tensor operator ij and the three independent components of the angular momentum vector) obey the same commutation relations as the infinitesimal generators of the SU(3) group, detailed above.

As such, the symmetry group of Hamiltonian for a linear isotropic 3D Harmonic oscillator is isomorphic to SU(3) group.

More systematically, operators such as the Ladder operators

  and  

can be constructed which raise and lower the eigenvalue of the Hamiltonian operator by 1.

The operators i and i are not hermitian; but hermitian operators can be constructed from different combinations of them, namely,

 .

There are nine such operators for i, j = 1, 2, 3.

The nine hermitian operators formed by the bilinear forms ij are controlled by the fundamental commutators

 
 

and seen to not commute among themselves. As a result, this complete set of operators don't share their eigenvectors in common, and they cannot be diagonalized simultaneously. The group is thus non-Abelian and degeneracies may be present in the Hamiltonian, as indicated.

The Hamiltonian of the 3D isotropic harmonic oscillator, when written in terms of the operator   amounts to

 .

The Hamiltonian has 8-fold degeneracy. A successive application of i and j on the left preserves the Hamiltonian invariant, since it increases Ni by 1 and decrease Nj by 1, thereby keeping the total

    constant. (cf. quantum harmonic oscillator)

Maximally commuting set of operators

edit

Since the operators belonging to the symmetry group of Hamiltonian do not always form an Abelian group, a common eigenbasis cannot be found that diagonalizes all of them simultaneously. Instead, we take the maximally commuting set of operators from the symmetry group of the Hamiltonian, and try to reduce the matrix representations of the group into irreducible representations.

Hilbert space of two systems

edit

The Hilbert space of two particles is the tensor product of the two Hilbert spaces of the two individual particles,

 

where   and   are the Hilbert space of the first and second particles, respectively.

The operators in each of the Hilbert spaces have their own commutation relations, and an operator of one Hilbert space commutes with an operator from the other Hilbert space. Thus the symmetry group of the two particle Hamiltonian operator is the superset of the symmetry groups of the Hamiltonian operators of individual particles. If the individual Hilbert spaces are N-dimensional, the combined Hilbert space is N2-dimensional.

Clebsch–Gordan coefficient in this case

edit

The symmetry group of the Hamiltonian is SU(3). As a result, the Clebsch–Gordan coefficients can be found by expanding the uncoupled basis vectors of the symmetry group of the Hamiltonian into its coupled basis. The Clebsch–Gordan series is obtained by block-diagonalizing the Hamiltonian through the unitary transformation constructed from the eigenstates which diagonalizes the maximal set of commuting operators.

Young tableaux

edit

A Young tableau (plural tableaux) is a method for decomposing products of an SU(N) group representation into a sum of irreducible representations. It provides the dimension and symmetry types of the irreducible representations, which is known as the Clebsch–Gordan series. Each irreducible representation corresponds to a single-particle state and a product of more than one irreducible representation indicates a multiparticle state.

Since the particles are mostly indistinguishable in quantum mechanics, this approximately relates to several permutable particles. The permutations of n identical particles constitute the symmetric group Sn. Every n-particle state of Sn that is made up of single-particle states of the fundamental N-dimensional SU(N) multiplet belongs to an irreducible SU(N) representation. Thus, it can be used to determine the Clebsch–Gordan series for any unitary group.[17]

Constructing the states

edit

Any two particle wavefunction  , where the indices 1,2 represents the state of particle 1 and 2, can be used to generate states of explicit symmetry using the symmetrizing and the anti-symmetrizing operators.[18]

 
 

where the   are the operator that interchanges the particles (Exchange operator).

The following relation follows:[18]-

 
 
 
 

thus,

 

Starting from a multiparticle state, we can apply   and   repeatedly to construct states that are:[18]

  1. Symmetric with respect to all particles.
  2. Antisymmetric with respect to all particles.
  3. Mixed symmetries, i.e. symmetric or antisymmetric with respect to some particles.

Constructing the tableaux

edit

Instead of using ψ, in Young tableaux, we use square boxes () to denote particles and i to denote the state of the particles.

 
A sample Young tableau. The number inside the boxes represents the state of the particles

The complete set of   particles are denoted by arrangements of   s, each with its own quantum number label (i).

The tableaux is formed by stacking boxes side by side and up-down such that the states symmetrised with respect to all particles are given in a row and the states anti-symmetrised with respect to all particles lies in a single column. Following rules are followed while constructing the tableaux:[17]

  1. A row must not be longer than the one before it.
  2. The quantum labels (numbers in the ) should not decrease while going left to right in a row.
  3. The quantum labels must strictly increase while going down in a column.

Case for N = 3

edit

For N = 3 that is in the case of SU(3), the following situation arises. In SU(3) there are three labels, they are generally designated by (u,d,s) corresponding to up, down and strange quarks which follows the SU(3) algebra. They can also be designated generically as (1,2,3). For a two-particle system, we have the following six symmetry states:

           

and the following three antisymmetric states:

 

The 1-column, 3-row tableau is the singlet, and so all tableaux of nontrivial irreps of SU(3) cannot have more than two rows. The representation D(p,q) has p q boxes on the top row and q boxes on the second row.

Clebsch–Gordan series from the tableaux

edit

Clebsch–Gordan series is the expansion of the tensor product of two irreducible representation into direct sum of irreducible representations.  . This can be easily found out from the Young tableaux.

Example of Clebsch–Gordan series for SU(3)

edit

The tensor product of a triplet with an octet reducing to a deciquintuplet (15), an anti-sextet, and a triplet

 

appears diagrammatically as[19]-

 
 

a total of 24 states. Using the same procedure, any direct product representation is easily reduced.

See also

edit

References

edit
  1. ^ P. Carruthers (1966) Introduction to Unitary symmetry, Interscience. online.
  2. ^ Introduction to Elementary Particles- David J. Griffiths, ISBN 978-3527406012, Chapter-1, Page33-38
  3. ^ Hall 2015 Section 6.2
  4. ^ Bargmann, V.; Moshinsky, M. (1961). "Group theory of harmonic oscillators (II). The integrals of Motion for the quadrupole-quadrupole interaction". Nuclear Physics. 23: 177–199. Bibcode:1961NucPh..23..177B. doi:10.1016/0029-5582(61)90253-X.
  5. ^ See eq. 3.65 in Pais, A. (1966). "Dynamical Symmetry in Particle Physics". Reviews of Modern Physics. 38 (2): 215–255. Bibcode:1966RvMP...38..215P. doi:10.1103/RevModPhys.38.215.
  6. ^ Pais, ibid. (3.66)
  7. ^ Hall 2015 Chapter 6
  8. ^ Hall 2015 Proposition 13.11
  9. ^ Hall 2015 Theorem 5.6
  10. ^ Hall 2015 Section 3.6
  11. ^ See the proof of Proposition 6.17 in Hall 2015
  12. ^ Hall 2015 Theorem 6.27 and Example 10.23
  13. ^ a b Greiner & Müller 2012, Ch. 10.15 Note: There is a typo in the final quoting of the result - in Equation 10.121 the first   should instead be a  .
  14. ^ Senner & Schulten
  15. ^ a b De Swart, J. J. (1963). "The Octet Model and its Clebsch-Gordan Coefficients" (PDF). Reviews of Modern Physics. 35 (4): 916–939. Bibcode:1963RvMP...35..916D. doi:10.1103/RevModPhys.35.916. (Erratum:  [De Swart, J. J. (1965). Reviews of Modern Physics. 37 (2): 326. Bibcode:1965RvMP...37..326D. doi:10.1103/RevModPhys.37.326.{{cite journal}}: CS1 maint: untitled periodical (link)])
  16. ^ Fradkin, D. M. (1965). "Three-Dimensional Isotropic Harmonic Oscillator and SU3". American Journal of Physics. 33 (3): 207–211. Bibcode:1965AmJPh..33..207F. doi:10.1119/1.1971373.
  17. ^ a b Arfken, George B.; Weber, Hans J. (2005). "4. Group Theory". Mathematical Methods For Physicists International Student Edition (6th ed.). Elsevier. pp. 241–320. ISBN 978-0-08-047069-6.
  18. ^ a b c http://hepwww.rl.ac.uk/Haywood/Group_Theory_Lectures/Lecture_4.pdf [bare URL PDF]
  19. ^ a b "Some Notes on Young Tableaux as useful for irreps for su(n)" (PDF). Archived from the original (PDF) on 2014-11-07. Retrieved 2014-11-07.