The number of known geometric equivalence classes of Weyl-Heisenberg SICs in dimension d equals the cardinality of the ideal class monoid of the real quadratic order of discriminant (d+1)(d-3) for d=4 to 90, with conjectures extending the equality and refining class-field predictions for the vector
SICs: Extending the list of solutions
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abstract
Zauner's conjecture asserts that $d^2$ equiangular lines exist in all $d$ complex dimensions. In quantum theory, the $d^2$ lines are dubbed a SIC, as they define a favoured standard informationally complete quantum measurement called a SIC-POVM. This note supplements A. J. Scott and M. Grassl [J. Math. Phys. 51 (2010), 042203] by extending the list of published numerical solutions. We provide a putative complete list of Weyl-Heisenberg covariant SICs with the known symmetries in dimensions $d\leq 90$, a single solution with Zauner's symmetry for every $d\leq 121$ and solutions with higher symmetry for $d=124,143,147,168,172,195,199,228,259$ and $323$.
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SIC-POVMs and orders of real quadratic fields
The number of known geometric equivalence classes of Weyl-Heisenberg SICs in dimension d equals the cardinality of the ideal class monoid of the real quadratic order of discriminant (d+1)(d-3) for d=4 to 90, with conjectures extending the equality and refining class-field predictions for the vector