Localizing multipartite entanglement with local and global measurements
- URL: http://arxiv.org/abs/2411.04080v1
- Date: Wed, 06 Nov 2024 17:58:35 GMT
- Title: Localizing multipartite entanglement with local and global measurements
- Authors: Christopher Vairogs, Samihr Hermes, Felix Leditzky,
- Abstract summary: We study the task of localizing multipartite entanglement in pure quantum states onto a subsystem by measuring the remaining systems.
We choose the $n$-tangle, the genuine multipartite entanglement concurrence and the concentratable entanglement (CE) as the underlying seed measure.
We show that our entanglement localization framework certifies the near-optimality of recently discussed local-measurement protocols.
- Score: 5.434628844260994
- License:
- Abstract: We study the task of localizing multipartite entanglement in pure quantum states onto a subsystem by measuring the remaining systems. To this end, we fix a multipartite entanglement measure and consider two quantities: the multipartite entanglement of assistance (MEA), defined as the entanglement measure averaged over the post-measurement states and maximized over arbitrary measurements; and the localizable multipartite entanglement (LME), defined in the same way but restricted to only local single-system measurements. We choose the $n$-tangle, the genuine multipartite entanglement concurrence and the concentratable entanglement (CE) as the underlying seed measure, and discuss the resulting MEA and LME quantities. First, we prove easily computable upper and lower bounds on MEA and LME and establish Lipschitz-continuity for the $n$-tangle and CE-based LME and MEA. Using these bounds we investigate the typical behavior of entanglement localization by deriving concentration inequalities for the MEA evaluated on Haar-random states and performing numerical studies for small tractable system sizes. We then turn our attention to protocols that transform graph states. We give a simple criterion based on a matrix equation to decide whether states with a specified $n$-tangle value can be obtained from a given graph state, providing no-go theorems for a broad class of such graph state transformations beyond the usual local Clifford plus local Pauli measurement framework. We generalize this analysis to weighted graph states and show that our entanglement localization framework certifies the near-optimality of recently discussed local-measurement protocols to transform uniformly weighted line graph states into GHZ states. Finally, we demonstrate how our MEA and LEA quantities can be used to detect phase transitions in transversal field Ising models.
Related papers
- Finite-Depth Preparation of Tensor Network States from Measurement [0.0]
We explore criteria on the local tensors for enabling deterministic state preparation via a single round of measurements.
We use these criteria to construct families of measurement-preparable states in one and two dimensions.
Our protocol even allows one to engineer preparable quantum states with a range of desired correlation lengths and entanglement properties.
arXiv Detail & Related papers (2024-04-26T00:37:00Z) - Gaussian Entanglement Measure: Applications to Multipartite Entanglement
of Graph States and Bosonic Field Theory [50.24983453990065]
An entanglement measure based on the Fubini-Study metric has been recently introduced by Cocchiarella and co-workers.
We present the Gaussian Entanglement Measure (GEM), a generalization of geometric entanglement measure for multimode Gaussian states.
By providing a computable multipartite entanglement measure for systems with a large number of degrees of freedom, we show that our definition can be used to obtain insights into a free bosonic field theory.
arXiv Detail & Related papers (2024-01-31T15:50:50Z) - Local measurement strategies for multipartite entanglement
quantification [3.249879651054463]
We show how local symmetric informationally complete POVMs enable multipartite entanglement with only a single measurement setting.
For all estimators, we provide both the classical post-processing cost and rigorous performance guarantees.
arXiv Detail & Related papers (2024-01-16T02:48:54Z) - Many-body entropies and entanglement from polynomially-many local measurements [0.26388783516590225]
We show that efficient estimation strategies exist under the assumption that all the spatial correlation lengths are finite.
We argue that our method could be practically useful to detect bipartite mixed-state entanglement for large numbers of qubits available in today's quantum platforms.
arXiv Detail & Related papers (2023-11-14T12:13:15Z) - Enhanced Entanglement in the Measurement-Altered Quantum Ising Chain [46.99825956909532]
Local quantum measurements do not simply disentangle degrees of freedom, but may actually strengthen the entanglement in the system.
This paper explores how a finite density of local measurement modifies a given state's entanglement structure.
arXiv Detail & Related papers (2023-10-04T09:51:00Z) - Manifestation of Rank-Tuned Weak Measurements Towards Featured State
Generation [0.0]
We show that rank-$2$ measurements can create only Greenberger Horne Zeilinger (GHZ)-class states while only W-class states are produced with rank-$4$ measurements.
In the case of multipartite states with an arbitrary number of qubits, we report that the average content of genuine multipartite entanglement increases with the decrease of the rank in the measurement operators.
arXiv Detail & Related papers (2022-08-19T13:02:24Z) - Quantum state tomography with tensor train cross approximation [84.59270977313619]
We show that full quantum state tomography can be performed for such a state with a minimal number of measurement settings.
Our method requires exponentially fewer state copies than the best known tomography method for unstructured states and local measurements.
arXiv Detail & Related papers (2022-07-13T17:56:28Z) - Controlling gain with loss: Bounds on localizable entanglement in
multi-qubit systems [0.0]
We study a number of paradigmatic pure states, including the generalized GHZ, the generalized W, Dicke, and the generalized Dicke states.
For the generalized GHZ and W states, we analytically derive bounds on localizable entanglement in terms of the entanglement present in the system prior to the measurement.
We extend the investigation numerically in the case of arbitrary multi-qubit pure states.
arXiv Detail & Related papers (2022-06-15T18:02:32Z) - Improving Metric Dimensionality Reduction with Distributed Topology [68.8204255655161]
DIPOLE is a dimensionality-reduction post-processing step that corrects an initial embedding by minimizing a loss functional with both a local, metric term and a global, topological term.
We observe that DIPOLE outperforms popular methods like UMAP, t-SNE, and Isomap on a number of popular datasets.
arXiv Detail & Related papers (2021-06-14T17:19:44Z) - Generalized quantum measurements with matrix product states:
Entanglement phase transition and clusterization [58.720142291102135]
We propose a method for studying the time evolution of many-body quantum lattice systems under continuous and site-resolved measurement.
We observe a peculiar phenomenon of measurement-induced particle clusterization that takes place only for frequent moderately strong measurements, but not for strong infrequent measurements.
arXiv Detail & Related papers (2021-04-21T10:36:57Z) - Observing a Topological Transition in Weak-Measurement-Induced Geometric
Phases [55.41644538483948]
Weak measurements in particular, through their back-action on the system, may enable various levels of coherent control.
We measure the geometric phases induced by sequences of weak measurements and demonstrate a topological transition in the geometric phase controlled by measurement strength.
Our results open new horizons for measurement-enabled quantum control of many-body topological states.
arXiv Detail & Related papers (2021-02-10T19:00:00Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.