Related papers: Entangling power of spin-j systems: a geometrical approach

Entangling power of spin-j systems: a geometrical approach

URL: http://arxiv.org/abs/2410.03361v1
Date: Fri, 4 Oct 2024 12:28:55 GMT
Title: Entangling power of spin-j systems: a geometrical approach
Authors: Eduardo Serrano-Ensástiga, Diego Morachis Galindo, Jesús A. Maytorena, Chryssomalis Chryssomalakos,
Abstract summary: Unitary gates with high entangling power are relevant for several quantum-enhanced technologies due to their entangling capabilities. We analyze the entangling power of spin systems by reformulating it as an inner product between vectors with components given by SU(2) invariants. We observe that extremal unitary gates exhibit entanglement distributions with high rotational symmetry, same that are linked to a convex combination of Husimi functions of certain states.
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License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Unitary gates with high entangling power are relevant for several quantum-enhanced technologies due to their entangling capabilities. For symmetric multiparticle systems, such as spin states or bosonic systems, the particle exchange symmetry restricts these gates and also the set of not-entangled states. In this work, we analyze the entangling power of spin systems by reformulating it as an inner product between vectors with components given by SU(2) invariants. This approach allows us to study this quantity for small-spin systems including the detection of the unitary gate that maximizes it for small spins. We observe that extremal unitary gates exhibit entanglement distributions with high rotational symmetry, same that are linked to a convex combination of Husimi functions of certain states. Furthermore, we explore the connection between entangling power and the Schmidt numbers admissible in some spin state subspaces. Thus, the geometrical approach presented here suggests new paths for studying entangling power linked to other concepts in quantum information theory.

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