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Sympathetic cooling schemes for separately trapped ions coupled via image currents
Cooling of particles to mK-temperatures is essential for a variety of experiments with trapped charged particles. However, many species of interest lack suitable electronic transitions for direct laser cooling. We study theoretically the remote sympathetic cooling of a single proton with laser-coole...
| Autores principales: | , , , , , , , , , , , , , , , , , , , , |
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| Lenguaje: | eng |
| Publicado: |
2021
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| Materias: | |
| Acceso en línea: | https://dx.doi.org/10.1088/1367-2630/ac55b3 http://cds.cern.ch/record/2806199 |
| _version_ | 1780972975629008896 |
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| author | Will, C. Bohman, M. Driscoll, T. Wiesinger, M. Abbass, F. Borchert, M.J. Devlin, J.A. Erlewein, S. Fleck, M. Latacz, B. Moller, R. Mooser, A. Popper, D. Wursten, E. Blaum, K. Matsuda, Y. Ospelkaus, C. Quint, W. Walz, J. Smorra, C. Ulmer, S. |
| author_facet | Will, C. Bohman, M. Driscoll, T. Wiesinger, M. Abbass, F. Borchert, M.J. Devlin, J.A. Erlewein, S. Fleck, M. Latacz, B. Moller, R. Mooser, A. Popper, D. Wursten, E. Blaum, K. Matsuda, Y. Ospelkaus, C. Quint, W. Walz, J. Smorra, C. Ulmer, S. |
| author_sort | Will, C. |
| collection | CERN |
| description | Cooling of particles to mK-temperatures is essential for a variety of experiments with trapped charged particles. However, many species of interest lack suitable electronic transitions for direct laser cooling. We study theoretically the remote sympathetic cooling of a single proton with laser-cooled $^{9}$Be$^{+}$ in a double-Penning-trap system. We investigate three different cooling schemes and find, based on analytical calculations and numerical simulations, that two of them are capable of achieving proton temperatures of about 10 mK with cooling times on the order of 10 s. In contrast, established methods such as feedback-enhanced resistive cooling with image-current detectors are limited to about 1 K in 100 s. Since the studied techniques are applicable to any trapped charged particle and allow spatial separation between the target ion and the cooling species, they enable a variety of precision measurements based on trapped charged particles to be performed at improved sampling rates and with reduced systematic uncertainties. |
| id | cern-2806199 |
| institution | Organización Europea para la Investigación Nuclear |
| language | eng |
| publishDate | 2021 |
| record_format | invenio |
| spelling | cern-28061992023-09-27T08:01:39Zdoi:10.1088/1367-2630/ac55b3http://cds.cern.ch/record/2806199engWill, C.Bohman, M.Driscoll, T.Wiesinger, M.Abbass, F.Borchert, M.J.Devlin, J.A.Erlewein, S.Fleck, M.Latacz, B.Moller, R.Mooser, A.Popper, D.Wursten, E.Blaum, K.Matsuda, Y.Ospelkaus, C.Quint, W.Walz, J.Smorra, C.Ulmer, S.Sympathetic cooling schemes for separately trapped ions coupled via image currentsnucl-exNuclear Physics - Experimentphysics.atom-phOther Fields of PhysicsCooling of particles to mK-temperatures is essential for a variety of experiments with trapped charged particles. However, many species of interest lack suitable electronic transitions for direct laser cooling. We study theoretically the remote sympathetic cooling of a single proton with laser-cooled $^{9}$Be$^{+}$ in a double-Penning-trap system. We investigate three different cooling schemes and find, based on analytical calculations and numerical simulations, that two of them are capable of achieving proton temperatures of about 10 mK with cooling times on the order of 10 s. In contrast, established methods such as feedback-enhanced resistive cooling with image-current detectors are limited to about 1 K in 100 s. Since the studied techniques are applicable to any trapped charged particle and allow spatial separation between the target ion and the cooling species, they enable a variety of precision measurements based on trapped charged particles to be performed at improved sampling rates and with reduced systematic uncertainties.Cooling of particles to mK-temperatures is essential for a variety of experiments with trapped charged particles. However, many species of interest lack suitable electronic transitions for direct laser cooling. We study theoretically the remote sympathetic cooling of a single proton with laser-cooled $^9$Be$^+$ in a double-Penning-trap system. We investigate three different cooling schemes and find, based on analytical calculations and numerical simulations, that two of them are capable of achieving proton temperatures of about 10 mK with cooling times on the order of 10 s. In contrast, established methods such as feedback-enhanced resistive cooling with image-current detectors are limited to about 1 K in 100 s. Since the studied techniques are applicable to any trapped charged particle and allow spatial separation between the target ion and the cooling species, they enable a variety of precision measurements based on trapped charged particles to be performed at improved sampling rates and with reduced systematic uncertainties.arXiv:2112.04818oai:cds.cern.ch:28061992021-12-09 |
| spellingShingle | nucl-ex Nuclear Physics - Experiment physics.atom-ph Other Fields of Physics Will, C. Bohman, M. Driscoll, T. Wiesinger, M. Abbass, F. Borchert, M.J. Devlin, J.A. Erlewein, S. Fleck, M. Latacz, B. Moller, R. Mooser, A. Popper, D. Wursten, E. Blaum, K. Matsuda, Y. Ospelkaus, C. Quint, W. Walz, J. Smorra, C. Ulmer, S. Sympathetic cooling schemes for separately trapped ions coupled via image currents |
| title | Sympathetic cooling schemes for separately trapped ions coupled via image currents |
| title_full | Sympathetic cooling schemes for separately trapped ions coupled via image currents |
| title_fullStr | Sympathetic cooling schemes for separately trapped ions coupled via image currents |
| title_full_unstemmed | Sympathetic cooling schemes for separately trapped ions coupled via image currents |
| title_short | Sympathetic cooling schemes for separately trapped ions coupled via image currents |
| title_sort | sympathetic cooling schemes for separately trapped ions coupled via image currents |
| topic | nucl-ex Nuclear Physics - Experiment physics.atom-ph Other Fields of Physics |
| url | https://dx.doi.org/10.1088/1367-2630/ac55b3 http://cds.cern.ch/record/2806199 |
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