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Main Authors: Li, Nicky Kai Hong, Dai, Xi, Muñoz-Arias, Manuel H., Reuer, Kevin, Huber, Marcus, Friis, Nicolai
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2504.21076
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author Li, Nicky Kai Hong
Dai, Xi
Muñoz-Arias, Manuel H.
Reuer, Kevin
Huber, Marcus
Friis, Nicolai
author_facet Li, Nicky Kai Hong
Dai, Xi
Muñoz-Arias, Manuel H.
Reuer, Kevin
Huber, Marcus
Friis, Nicolai
contents Detecting genuine multipartite entanglement (GME) is a state-characterization task that benchmarks coherence and experimental control in quantum systems. Existing GME tests often require joint measurements on many qubits, posing challenges for systems like time-bin encoded qubits and microwave photons from superconducting circuits, where qubit connectivity is limited or measurement noise grows with the number of jointly measured qubits. Here we introduce versatile GME and $k$-inseparability criteria applicable to any state, which only require measuring $O(n^2)$ out of $2^n$ (at most) $m$-body stabilizers of $n$-qubit target graph states, with $m$ upper-bounded by twice the graph's maximum degree. For cluster or ring-graph states, only constant-weight stabilizers are needed. Using semidefinite programming (and sometimes graph-local complementations), we can reduce the number or weight of required stabilizers. Analytical and numerical results show that our criteria are noise-robust and may infer state infidelity from certified $k$-inseparability in microwave photonic graph states generated under realistic conditions.
format Preprint
id arxiv_https___arxiv_org_abs_2504_21076
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Detecting genuine multipartite entanglement in multi-qubit devices with restricted measurements
Li, Nicky Kai Hong
Dai, Xi
Muñoz-Arias, Manuel H.
Reuer, Kevin
Huber, Marcus
Friis, Nicolai
Quantum Physics
Detecting genuine multipartite entanglement (GME) is a state-characterization task that benchmarks coherence and experimental control in quantum systems. Existing GME tests often require joint measurements on many qubits, posing challenges for systems like time-bin encoded qubits and microwave photons from superconducting circuits, where qubit connectivity is limited or measurement noise grows with the number of jointly measured qubits. Here we introduce versatile GME and $k$-inseparability criteria applicable to any state, which only require measuring $O(n^2)$ out of $2^n$ (at most) $m$-body stabilizers of $n$-qubit target graph states, with $m$ upper-bounded by twice the graph's maximum degree. For cluster or ring-graph states, only constant-weight stabilizers are needed. Using semidefinite programming (and sometimes graph-local complementations), we can reduce the number or weight of required stabilizers. Analytical and numerical results show that our criteria are noise-robust and may infer state infidelity from certified $k$-inseparability in microwave photonic graph states generated under realistic conditions.
title Detecting genuine multipartite entanglement in multi-qubit devices with restricted measurements
topic Quantum Physics
url https://arxiv.org/abs/2504.21076