AN Multiplicity Rules And Schur Functions
Abstract
We show that a specialization in Weyl character formula can be carried out in such a way that its right-hand side becomes simply a Schur Function. For this, we need the use of fundamental weights. In the generic definition, an Elementary Schur Function SQ(x1,x2,..,xQ) of degree Q is known to be defined by some polynomial of Q indeterminates x1,x2,..,xQ . It is also known that definition of Elementary Schur Functions can be generalized in such a way that for any partition (Qk) of weight Q and length k one has a Generalized Schur Function S(Qk)(x1,x2,..,xQ). When they are considered for AN-1 Lie algebras, a kind of degeneration occurs for these generic definitions. This is mainly due to the fact that, for an AN-1 Lie algebra, only a finite number of indeterminates, namely (N-1), can be independent. This leads us to define Degenerated Schur Functions by taking, for Q > N-1, all the indeterminates xQ to be non-linearly dependent on first (N-1) indeterminates x1,x2,..,xN-1. With this in mind, we show that for each and every dominant weight of AN-1 we always have a (Degenerated) Schur Function which provides the right-hand side of Weyl character formula. Generalized Schur Functions are known to be expressed by determinants of some matrices of Elementary Schur Functions. We would like to call these expressions multiplicity rules. This is mainly due to the fact that, to calculate weight multiplicities, these rules give us an efficient method which works equally well no matter how big is the rank of algebras or the dimensions of representations.
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