Spatial non-adiabatic passage using geometric phases

Albert Benseny; Anthony Kiely; Yongping Zhang; Thomas Busch; Andreas Ruschhaupt

doi:10.1140/epjqt/s40507-017-0056-x

Spatial non-adiabatic passage using geometric phases

Albert Benseny
, Anthony Kiely
, Yongping Zhang
, Thomas Busch
, Andreas Ruschhaupt

School of Physics

Research output: Contribution to journal › Article › peer-review

Abstract

Quantum technologies based on adiabatic techniques can be highly effective, but often at the cost of being very slow. Here we introduce a set of experimentally realistic, non-adiabatic protocols for spatial state preparation, which yield the same fidelity as their adiabatic counterparts, but on fast timescales. In particular, we consider a charged particle in a system of three tunnel-coupled quantum wells, where the presence of a magnetic field can induce a geometric phase during the tunnelling processes. We show that this leads to the appearance of complex tunnelling amplitudes and allows for the implementation of spatial non-adiabatic passage. We demonstrate the ability of such a system to transport a particle between two different wells and to generate a delocalised superposition between the three traps with high fidelity in short times.

Original language	English
Article number	3
Journal	EPJ Quantum Technology
Volume	4
Issue number	1
DOIs	https://doi.org/10.1140/epjqt/s40507-017-0056-x
Publication status	Published - 1 Dec 2017

Keywords

Complex tunnelling
Geometric phases
Shortcuts to adiabaticity

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10.1140/epjqt/s40507-017-0056-x

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abstract = "Quantum technologies based on adiabatic techniques can be highly effective, but often at the cost of being very slow. Here we introduce a set of experimentally realistic, non-adiabatic protocols for spatial state preparation, which yield the same fidelity as their adiabatic counterparts, but on fast timescales. In particular, we consider a charged particle in a system of three tunnel-coupled quantum wells, where the presence of a magnetic field can induce a geometric phase during the tunnelling processes. We show that this leads to the appearance of complex tunnelling amplitudes and allows for the implementation of spatial non-adiabatic passage. We demonstrate the ability of such a system to transport a particle between two different wells and to generate a delocalised superposition between the three traps with high fidelity in short times.",

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AU - Benseny, Albert

AU - Kiely, Anthony

AU - Zhang, Yongping

AU - Busch, Thomas

AU - Ruschhaupt, Andreas

N1 - Publisher Copyright: © The Author(s) 2017.

PY - 2017/12/1

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N2 - Quantum technologies based on adiabatic techniques can be highly effective, but often at the cost of being very slow. Here we introduce a set of experimentally realistic, non-adiabatic protocols for spatial state preparation, which yield the same fidelity as their adiabatic counterparts, but on fast timescales. In particular, we consider a charged particle in a system of three tunnel-coupled quantum wells, where the presence of a magnetic field can induce a geometric phase during the tunnelling processes. We show that this leads to the appearance of complex tunnelling amplitudes and allows for the implementation of spatial non-adiabatic passage. We demonstrate the ability of such a system to transport a particle between two different wells and to generate a delocalised superposition between the three traps with high fidelity in short times.

AB - Quantum technologies based on adiabatic techniques can be highly effective, but often at the cost of being very slow. Here we introduce a set of experimentally realistic, non-adiabatic protocols for spatial state preparation, which yield the same fidelity as their adiabatic counterparts, but on fast timescales. In particular, we consider a charged particle in a system of three tunnel-coupled quantum wells, where the presence of a magnetic field can induce a geometric phase during the tunnelling processes. We show that this leads to the appearance of complex tunnelling amplitudes and allows for the implementation of spatial non-adiabatic passage. We demonstrate the ability of such a system to transport a particle between two different wells and to generate a delocalised superposition between the three traps with high fidelity in short times.

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KW - Shortcuts to adiabaticity

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Spatial non-adiabatic passage using geometric phases

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Keywords

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