An Explicit Scott-Type Bound for Absolutely Maximally Entangled States with Arbitrary Defect

Abstract

Absolutely maximally entangled (AME) states and, more generally, k-uniform states in (q) n are central objects in multipartite entanglement theory, with applications to quantum secret sharing, quantum masking, and quantum error correction. In the extremal case k= n/2, Scott (2004) proved a sharp nonexistence bound showing that AME states cannot exist once the number of parties n exceeds a threshold of order 2q2 (with a parity dependence on n), where q is the local dimension. Recently, Ning et al.\ studied defective AME states (i.e., k= n/2-l with l>0), gave explicit Scott-type bounds for defects l=1,2 and conjectured a general (2l+2)q2+o(q2) behavior. In this paper, we solve this conjecture and establish a fully explicit Scott-type upper bound for AME states with arbitrary defect l 0, yielding Scott's bound for l=0 and Ning et al.'s bounds for l=1,2 as special cases. Equivalently, this gives nonexistence bounds for one-dimensional pure quantum error-correcting codes near the quantum Singleton regime. The proof uses a truncated MacWilliams linear-programming system and an explicit infeasibility certificate. As a direct application, we derive explicit asymptotic upper bounds on k/n for fixed local dimension q, improving the implicit upper bounds given by Ning et al.