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Autori principali: Koutromanos, Dimitris, Stefanatos, Dionisis, Paspalakis, Emmanuel
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2412.17489
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author Koutromanos, Dimitris
Stefanatos, Dionisis
Paspalakis, Emmanuel
author_facet Koutromanos, Dimitris
Stefanatos, Dionisis
Paspalakis, Emmanuel
contents Coupled spins form composite quantum systems which play an important role in many quantum technology applications, with an essential task often being the efficient generation of entanglement between two constituent qubits. The simplest such system is a pair of spins-$1/2$ coupled with Ising interaction, and in previous works various quantum control methods such as adiabatic processes, shortcuts to adiabaticity and optimal control have been employed to quickly generate there one of the maximally entangled Bell states. In this study, we use machine learning and optimization methods to produce maximally entangled states in minimum time, with the Rabi frequency and the detuning used as bounded control functions. We do not target a specific maximally entangled state, like the preceding studies, but rather find the controls which maximize the concurrence, leading thus automatically the system to the closest such state in shorter time. By increasing the bounds of the control functions we observe that the corresponding optimally selected maximally entangled state also changes and the necessary time to reach it is reduced. The present work demonstrates also that machine learning and optimization offer efficient and flexible techniques for the fast generation of entanglement in coupled spin systems, and we plan to extent it to systems involving more spins, for example spin chains.
format Preprint
id arxiv_https___arxiv_org_abs_2412_17489
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Fast generation of entanglement between coupled spins using optimization and deep learning methods
Koutromanos, Dimitris
Stefanatos, Dionisis
Paspalakis, Emmanuel
Quantum Physics
Coupled spins form composite quantum systems which play an important role in many quantum technology applications, with an essential task often being the efficient generation of entanglement between two constituent qubits. The simplest such system is a pair of spins-$1/2$ coupled with Ising interaction, and in previous works various quantum control methods such as adiabatic processes, shortcuts to adiabaticity and optimal control have been employed to quickly generate there one of the maximally entangled Bell states. In this study, we use machine learning and optimization methods to produce maximally entangled states in minimum time, with the Rabi frequency and the detuning used as bounded control functions. We do not target a specific maximally entangled state, like the preceding studies, but rather find the controls which maximize the concurrence, leading thus automatically the system to the closest such state in shorter time. By increasing the bounds of the control functions we observe that the corresponding optimally selected maximally entangled state also changes and the necessary time to reach it is reduced. The present work demonstrates also that machine learning and optimization offer efficient and flexible techniques for the fast generation of entanglement in coupled spin systems, and we plan to extent it to systems involving more spins, for example spin chains.
title Fast generation of entanglement between coupled spins using optimization and deep learning methods
topic Quantum Physics
url https://arxiv.org/abs/2412.17489