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Main Authors: Suleimen, Yelnury, Podlesnyy, Artem, Akopyan, Lianna A., Sterligov, Nikita, Lakhmanskaya, Olga, Anikin, Evgeny, Matveev, Arthur, Lakhmanskiy, Kirill
Format: Preprint
Published: 2022
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Online Access:https://arxiv.org/abs/2211.07121
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author Suleimen, Yelnury
Podlesnyy, Artem
Akopyan, Lianna A.
Sterligov, Nikita
Lakhmanskaya, Olga
Anikin, Evgeny
Matveev, Arthur
Lakhmanskiy, Kirill
author_facet Suleimen, Yelnury
Podlesnyy, Artem
Akopyan, Lianna A.
Sterligov, Nikita
Lakhmanskaya, Olga
Anikin, Evgeny
Matveev, Arthur
Lakhmanskiy, Kirill
contents We describe the design and operation of a surface-electrode Paul trap for parallel entangling gate implementation. In particular, we demonstrate the possibility of separating or coupling ion motion by adjusting the DC-voltages on a set of electrodes and show the possibility of parallel MS-gate operations for specific voltage configurations. We verify the scalability of this approach and characterize the performance of these gates in the presence of the finite phonon mode occupation and of the finite drift of the phonon frequencies. Additionally, we investigate how the number of ions per individual trapping site and anharmonic potential terms affect the coupling between the wells.
format Preprint
id arxiv_https___arxiv_org_abs_2211_07121
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle Surface trap with adjustable ion couplings for scalable and parallel gates
Suleimen, Yelnury
Podlesnyy, Artem
Akopyan, Lianna A.
Sterligov, Nikita
Lakhmanskaya, Olga
Anikin, Evgeny
Matveev, Arthur
Lakhmanskiy, Kirill
Quantum Physics
We describe the design and operation of a surface-electrode Paul trap for parallel entangling gate implementation. In particular, we demonstrate the possibility of separating or coupling ion motion by adjusting the DC-voltages on a set of electrodes and show the possibility of parallel MS-gate operations for specific voltage configurations. We verify the scalability of this approach and characterize the performance of these gates in the presence of the finite phonon mode occupation and of the finite drift of the phonon frequencies. Additionally, we investigate how the number of ions per individual trapping site and anharmonic potential terms affect the coupling between the wells.
title Surface trap with adjustable ion couplings for scalable and parallel gates
topic Quantum Physics
url https://arxiv.org/abs/2211.07121