Jordan map

In theoretical physics, the Jordan map, often also called the Jordan–Schwinger map is a map from matrices Mij to bilinear expressions of quantum oscillators which expedites computation of representations of Lie Algebras occurring in physics. It was introduced by Pascual Jordan in 1935[1] and was utilized by Julian Schwinger[2] in 1952 to re-work out the theory of quantum angular momentum efficiently, given that map’s ease of organizing the (symmetric) representations of su(2) in Fock space.

The map utilizes several creation and annihilation operators a^\dagger_i and a^{\,}_i of routine use in quantum field theories and many-body problems, each pair representing a quantum harmonic oscillator. The commutation relations of creation and annihilation operators in a multiple-boson system are,

[a^{\,}_i, a^\dagger_j] \equiv a^{\,}_i a^\dagger_j - a^\dagger_ja^{\,}_i = \delta_{i j},
[a^\dagger_i, a^\dagger_j] = [a^{\,}_i, a^{\,}_j] = 0,

where [\ \ , \ \ ] is the commutator and \delta_{i j} is the Kronecker delta.

These operators change the eigenvalues of the number operator,

N = \sum_i n_i = \sum_i a^\dagger_i a^{\,}_i,

by one, as for multidimensional quantum harmonic oscillators.

The Jordan map from a set of matrices Mij to Fock space bilinear operators M,

{\mathbf M}  \qquad \longmapsto \qquad   M \equiv  \sum_{i,j}  a^\dagger_i  {\mathbf M}_{ij}    a_j  ~,

is clearly a Lie Algebra isomorphism, i.e. the operators M satisfy the same commutation relations as the matrices M.

For example, the image of the Pauli matrices of SU(2) in this map,

{\vec  J} \equiv    {\mathbf  a}^\dagger \cdot\frac{ {\vec  \sigma } } {2} \cdot    {\mathbf a}^{\,}   ~,

for two-vector as, and as satisfy the same commutation relations of SU(2) as well, and moreover, by reliance on the completeness relation for Pauli matrices,

J^2\equiv {\vec  J} \cdot {\vec  J} = \frac{N}{2} \left ( \frac{N}{2}+1\right )~.

This is the starting point of Schwinger’s treatment of the theory of quantum angular momentum, predicated on the action of these operators on Fock states built of arbitrary higher powers of such operators. For instance, acting on an (unnormalized) Fock eigenstate,

J^2~   a^{\dagger k}_1  a^{\dagger n}_2  |0\rangle=   \frac{k+n}{2} \left ( \frac{k+n}{2}+1\right ) ~  a^{\dagger k}_1  a^{\dagger n}_2 |0\rangle ~,

while

J_z ~   a^{\dagger k}_1  a^{\dagger n}_2  |0\rangle=   \frac{1}{2} \left ( k-n\right ) ~  a^{\dagger k}_1  a^{\dagger n}_2 |0\rangle ~,

so that, for j=(k+n)/2,   m=(k−n)/2, this is proportional to the eigenstate |j,m.


Antisymmetric representations of Lie algebras can further be accommodated by use of the fermionic operators b^\dagger_i and b^{\,}_i, as also suggested by Jordan. For fermions, the commutator is replaced by the anticommutator \{\ \ , \ \ \},

\{b^{\,}_i, b^\dagger_j\} \equiv b^{\,}_i b^\dagger_j +b^\dagger_j b^{\,}_i = \delta_{i j},
\{b^\dagger_i, b^\dagger_j\} = \{b^{\,}_i, b^{\,}_j\} = 0.

Therefore, exchanging disjoint (i.e. i \ne j) operators in a product of creation of annihilation operators will reverse the sign in fermion systems, but not in boson systems.

References

  1. Jordan, Pascual (1935). "Der Zusammenhang der symmetrischen und linearen Gruppen und das Mehrkörperproblem", Zeitschrift für Physik 94, Issue 7-8, 531-535
  2. Schwinger, J. (1952). "On Angular Momentum", Unpublished Report, Harvard University, Nuclear Development Associates, Inc., United States Department of Energy (through predecessor agency the Atomic Energy Commission), Report Number NYO-3071 (January 26, 1952).


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