Typical Entanglement of Superpositions

Abstract

We investigate universal entanglement properties inherent to superpositions of randomized states. We find that an m-fold superposition of typical states may be classified into two distinct entanglement classes via the 2nd Rényi entropy density s2. The maximally entangled regime is defined by s2 (2), for which superposition adds no additional entanglement. The sub-maximally entangled regime, s2< 2, instead constrains the reduced density matrices of independent components to be orthogonal in the thermodynamic limit, which fixes the entanglement of the superposition to a logarithmic enhancement ΔS(m)= (m). As a consequence, an exponentially large number of superpositions is required to transition from the sub-maximally entangled class to maximal entanglement. We explicitly calculate s2 and the logarithmic enhancement, and demonstrate orthogonality for two canonical examples of the sub-maximally entangled regime (superpositions of pure Gaussian states and of random matrix-product states). We also examine the entanglement of superpositions of random stabilizer states, and discuss their relaxation to the Haar limit.

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