Prepare-and-Magic: Semi-Device Independent Magic Certification in the Prepare-and-Measure Scenario (2506.02226v1)

Abstract: Non-stabilizerness is an essential resource for quantum computational advantage, as stabilizer states admit efficient classical simulation. We develop a semi-device-independent framework for certifying non-stabilizer states in prepare-and-measure (PAM) scenarios, relying only on assumptions about the system's dimension. Within this framework, we introduce dimensional witnesses that can distinguish stabilizer from non-stabilizer states, and we provide analytical proofs that threshold violations of these witnesses certify non-stabilizerness. In the simplest setting-three preparations, two measurements, and qubit systems-surpassing a specific threshold guarantees that at least one prepared state lies outside the stabilizer polytope. We extend this approach by linking it to quantum random access codes, also generalizing our results to qutrit systems and introducing a necessary condition for certifying non-stabilizerness based on state overlaps (Gram matrices). These results offer a set of semi-device-independent tools for practically and systematically verifying non-stabilizer states using dimensional witnesses in PAM scenarios.