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Comparative numerical studies of ion traps with integrated optical cavities

Comparative numerical studies of ion traps with integrated optical cavities
Comparative numerical studies of ion traps with integrated optical cavities
We study a range of radio-frequency ion trap geometries and investigate the effect of integrating dielectric cavity mirrors on their trapping potential using numerical modelling. We compare five different ion trap geometries with the aim to identify ion trap and cavity configurations that are best suited for achieving small cavity volumes and thus large ion-photon coupling as required for scalable quantum information networks. In particular, we investigate the trapping potential distortions caused by the dielectric material of the cavity mirrors in all 3 dimensions for different mirror orientations with respect to the trapping electrodes. We also analyze the effect of the mirror material properties such as dielectric constants and surface conductivity, and study the effect of surface charges on the mirrors. As well as perfectly symmetric systems, we also consider traps with optical cavities that are not centrally aligned where we find a spatial displacement of the trap center and asymmetry of the resulting trap only at certain cavity orientations. The best trap-cavity configurations with the smallest trapping potential distortions are those where the cavities are aligned along the major symmetry axis of the electrode geometries. These cavity configurations also appear to be the most stable with respect to any mirror misalignment. Although we consider particular trap sizes in our study, the presented results can be easily generalized and scaled to different trap dimensions.
Podoliak, Nina
0908b951-00a7-48a5-bc82-631640910b9c
Takahashi, Hiroki
637b5ded-fe36-40f8-950c-2622296a4cfe
Keller, Matthias
d55e5cb9-c8b3-4489-bf2e-1e80fee56a1d
Horak, Peter
520489b5-ccc7-4d29-bb30-c1e36436ea03
Podoliak, Nina
0908b951-00a7-48a5-bc82-631640910b9c
Takahashi, Hiroki
637b5ded-fe36-40f8-950c-2622296a4cfe
Keller, Matthias
d55e5cb9-c8b3-4489-bf2e-1e80fee56a1d
Horak, Peter
520489b5-ccc7-4d29-bb30-c1e36436ea03

Podoliak, Nina, Takahashi, Hiroki, Keller, Matthias and Horak, Peter (2016) Comparative numerical studies of ion traps with integrated optical cavities. Physical Review Applied, 6 (4), [044008]. (doi:10.1103/PhysRevApplied.6.044008).

Record type: Article

Abstract

We study a range of radio-frequency ion trap geometries and investigate the effect of integrating dielectric cavity mirrors on their trapping potential using numerical modelling. We compare five different ion trap geometries with the aim to identify ion trap and cavity configurations that are best suited for achieving small cavity volumes and thus large ion-photon coupling as required for scalable quantum information networks. In particular, we investigate the trapping potential distortions caused by the dielectric material of the cavity mirrors in all 3 dimensions for different mirror orientations with respect to the trapping electrodes. We also analyze the effect of the mirror material properties such as dielectric constants and surface conductivity, and study the effect of surface charges on the mirrors. As well as perfectly symmetric systems, we also consider traps with optical cavities that are not centrally aligned where we find a spatial displacement of the trap center and asymmetry of the resulting trap only at certain cavity orientations. The best trap-cavity configurations with the smallest trapping potential distortions are those where the cavities are aligned along the major symmetry axis of the electrode geometries. These cavity configurations also appear to be the most stable with respect to any mirror misalignment. Although we consider particular trap sizes in our study, the presented results can be easily generalized and scaled to different trap dimensions.

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More information

Accepted/In Press date: 16 September 2016
e-pub ahead of print date: 17 October 2016
Published date: 17 October 2016
Additional Information: Funded by EPSRC: UK Quantum Technology Hub: NQIT - Networked Quantum Information Technologies (EP/M013243/1)
Related URLs:
Organisations: Optoelectronics Research Centre, Quantum, Light & Matter Group
Learn more about Optoelectronics Research Centre research

Identifiers

Local EPrints ID: 401738
URI: http://eprints.soton.ac.uk/id/eprint/401738
DOI: doi:10.1103/PhysRevApplied.6.044008
PURE UUID: 8a80a931-5c42-443b-94ff-922df927c6ac
ORCID for Nina Podoliak: ORCID iD orcid.org/0000-0002-3146-0355
ORCID for Peter Horak: ORCID iD orcid.org/0000-0002-8710-8764

Catalogue record

Date deposited: 20 Oct 2016 13:43
Last modified: 15 Mar 2024 03:36

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Contributors

Author: Nina Podoliak ORCID iD
Author: Hiroki Takahashi
Author: Matthias Keller
Author: Peter Horak ORCID iD

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