The Existence of Diagonal Quantum Latin Squares with Maximum Cardinality

Abstract

A quantum Latin square of order \(n\), denoted by \(QLS(n)\), is an \(n × n\) square whose entries are unit column vectors in the \(n\)-dimensional Hilbert space \(Hn\), such that each row and each column forms an orthonormal basis of \(Hn\). The cardinality of a QLS(n) is the number of distinct vectors up to a global phase in the array. A \(QLS(n)\) whose main diagonal and anti-diagonal each forms an orthonormal basis of \(Hn\) is called a diagonal quantum Latin square (\(DQLS(n)\)). In this paper, we focus on the existence of the \(DQLS(n)\) with maximum cardinality (MCDQLS(n)). By employing direct constructions based on row-quantum Latin rectangle and special complete mapping, together with the recursive techniques such as the singular direct product construction, We have almost completely determined the existence of \(MCDQLS(n)\), except for a few exceptional cases. This result is based on the study of the existence of idempotent \(QLS(n)\) with maximum cardinality (\(MCQLS(n)\)), and implies an existence result for pandiagonal quantum Latin squares with maximum cardinality (\(MCPQLS(n)\)).