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Research PaperResearchia:202607.08080

Typical Entanglement of Superpositions

Damien Quinn

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 $s_2$. The maximally entangled regime is defined by $s_2 \sim \ln (2)$, for which superposition adds no additional entanglement. The sub-maximally entangled regime, $s_2<\ln 2$, instead constrains the reduced density matrices of independent components to...

Submitted: July 8, 2026Subjects: Quantum Physics; Quantum Computing

Description / Details

We investigate universal entanglement properties inherent to superpositions of randomized states. We find that an mm-fold superposition of typical states may be classified into two distinct entanglement classes via the 2nd Rényi entropy density s2s_2. The maximally entangled regime is defined by s2ln(2)s_2 \sim \ln (2), for which superposition adds no additional entanglement. The sub-maximally entangled regime, s2<ln2s_2<\ln 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)=ln(m)ΔS(m)=\ln (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 s2s_2 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.


Source: arXiv:2607.06474v1 - http://arxiv.org/abs/2607.06474v1 PDF: https://arxiv.org/pdf/2607.06474v1 Original Link: http://arxiv.org/abs/2607.06474v1

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Date:
Jul 8, 2026
Topic:
Quantum Computing
Area:
Quantum Physics
Comments:
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