Spin Leonard pairs and the zero diagonal space

Abstract

We consider a Leonard pair A, A* of linear maps on a vector space V that has finite positive dimension. This Leonard pair A,A* is said to have spin whenever there exist invertible linear maps W : V V and W* : V V such that W A = A W and W* A* = A* W* and W A* W-1 = (W*)-1 A W*. Let \θ*i\i=0d denote a standard ordering of the eigenvalues of A*. There is a related sequence of scalars \ai\i=0d called intersection numbers. The Leonard pair A,A* is called self-dual whenever \θ*i\i=0d is a standard ordering of the eigenvalues of A. We obtain the following results under the assumption that the ground field is algebraically closed and d ≥ 3. We show that a Leonard pair A,A* on V has spin if and only if both (i) A,A* is self-dual; (ii) there exist scalars f0,f1,f2, f3 (not all zero) such that f0 + f1 θ*i + f2 ai + f3 ai θ*i = 0 for 0 ≤ i ≤ d. We also classify the Leonard pairs A,A* on V that satisfy (ii) without assuming (i). To do this we bring in the following maps. For 0 ≤ i ≤ d let E*i : V V denote the projection onto the θ*i-eigenspace of A*. Let Z(A,A*) denote the set of elements X in Span\I, A*, A, A A*\ such that E*i X E*i= 0 for 0 ≤ i ≤ d. We call Z(A,A*) the zero diagonal space of A,A*. As we will see, Z(A,A*) ≠ 0 if and only if the above condition (ii) holds. As we investigate the case Z(A,A*) ≠ 0 in detail, we break the problem into 13 cases called types; these are the q-Racah type and its relatives. For each type we give a necessary and sufficient condition for Z(A,A*) =0. For each type we give an explicit basis for Z(A,A*).