Solid-state magnetic traps and lattices
J. Knörzer, M. J. A. Schuetz, G. Giedke, H. Huebl, M. Weiler, M. D. Lukin, and J. I. Cirac
American Physical Society (APS)
Published 2018
American Physical Society (APS)
Published 2018
| Publication Date: |
2018-06-30
|
|---|---|
| Publisher: |
American Physical Society (APS)
|
| Print ISSN: |
1098-0121
|
| Electronic ISSN: |
1095-3795
|
| Topics: |
Physics
|
| Keywords: |
Surface physics, nanoscale physics, low-dimensional systems
|
| Published by: |
| _version_ | 1836398993342464001 |
|---|---|
| autor | J. Knörzer, M. J. A. Schuetz, G. Giedke, H. Huebl, M. Weiler, M. D. Lukin, and J. I. Cirac |
| beschreibung | Author(s): J. Knörzer, M. J. A. Schuetz, G. Giedke, H. Huebl, M. Weiler, M. D. Lukin, and J. I. Cirac This work examines the feasibility of magnetic traps and lattices for electrons in semiconductors. The authors provide a general theoretical framework and show that thermally stable traps can be generated by magnetically driving the particle’s internal spin transition, akin to optical dipole traps for ultracold atoms. In close analogy to optical lattices, arrays of magnetic traps, i.e. magnetic lattices, are proposed as a platform for quantum simulation of exotic Hubbard models. Furthermore, two specific implementations are discussed in detail, one based on a superconducting circuit and another one based on surface acoustic waves. [Phys. Rev. B 97, 235451] Published Fri Jun 29, 2018 |
| citation_standardnr | 6295935 |
| datenlieferant | ipn_articles |
| feed_id | 52538 |
| feed_publisher | American Physical Society (APS) |
| feed_publisher_url | http://www.aps.org/ |
| insertion_date | 2018-06-30 |
| journaleissn | 1095-3795 |
| journalissn | 1098-0121 |
| publikationsjahr_anzeige | 2018 |
| publikationsjahr_facette | 2018 |
| publikationsjahr_intervall | 7984:2015-2019 |
| publikationsjahr_sort | 2018 |
| publisher | American Physical Society (APS) |
| quelle | Physical Review B |
| relation | http://link.aps.org/doi/10.1103/PhysRevB.97.235451 |
| schlagwort | Surface physics, nanoscale physics, low-dimensional systems |
| search_space | articles |
| shingle_author_1 | J. Knörzer, M. J. A. Schuetz, G. Giedke, H. Huebl, M. Weiler, M. D. Lukin, and J. I. Cirac |
| shingle_author_2 | J. Knörzer, M. J. A. Schuetz, G. Giedke, H. Huebl, M. Weiler, M. D. Lukin, and J. I. Cirac |
| shingle_author_3 | J. Knörzer, M. J. A. Schuetz, G. Giedke, H. Huebl, M. Weiler, M. D. Lukin, and J. I. Cirac |
| shingle_author_4 | J. Knörzer, M. J. A. Schuetz, G. Giedke, H. Huebl, M. Weiler, M. D. Lukin, and J. I. Cirac |
| shingle_catch_all_1 | Solid-state magnetic traps and lattices Surface physics, nanoscale physics, low-dimensional systems Author(s): J. Knörzer, M. J. A. Schuetz, G. Giedke, H. Huebl, M. Weiler, M. D. Lukin, and J. I. Cirac This work examines the feasibility of magnetic traps and lattices for electrons in semiconductors. The authors provide a general theoretical framework and show that thermally stable traps can be generated by magnetically driving the particle’s internal spin transition, akin to optical dipole traps for ultracold atoms. In close analogy to optical lattices, arrays of magnetic traps, i.e. magnetic lattices, are proposed as a platform for quantum simulation of exotic Hubbard models. Furthermore, two specific implementations are discussed in detail, one based on a superconducting circuit and another one based on surface acoustic waves. [Phys. Rev. B 97, 235451] Published Fri Jun 29, 2018 J. Knörzer, M. J. A. Schuetz, G. Giedke, H. Huebl, M. Weiler, M. D. Lukin, and J. I. Cirac American Physical Society (APS) 1098-0121 10980121 1095-3795 10953795 |
| shingle_catch_all_2 | Solid-state magnetic traps and lattices Surface physics, nanoscale physics, low-dimensional systems Author(s): J. Knörzer, M. J. A. Schuetz, G. Giedke, H. Huebl, M. Weiler, M. D. Lukin, and J. I. Cirac This work examines the feasibility of magnetic traps and lattices for electrons in semiconductors. The authors provide a general theoretical framework and show that thermally stable traps can be generated by magnetically driving the particle’s internal spin transition, akin to optical dipole traps for ultracold atoms. In close analogy to optical lattices, arrays of magnetic traps, i.e. magnetic lattices, are proposed as a platform for quantum simulation of exotic Hubbard models. Furthermore, two specific implementations are discussed in detail, one based on a superconducting circuit and another one based on surface acoustic waves. [Phys. Rev. B 97, 235451] Published Fri Jun 29, 2018 J. Knörzer, M. J. A. Schuetz, G. Giedke, H. Huebl, M. Weiler, M. D. Lukin, and J. I. Cirac American Physical Society (APS) 1098-0121 10980121 1095-3795 10953795 |
| shingle_catch_all_3 | Solid-state magnetic traps and lattices Surface physics, nanoscale physics, low-dimensional systems Author(s): J. Knörzer, M. J. A. Schuetz, G. Giedke, H. Huebl, M. Weiler, M. D. Lukin, and J. I. Cirac This work examines the feasibility of magnetic traps and lattices for electrons in semiconductors. The authors provide a general theoretical framework and show that thermally stable traps can be generated by magnetically driving the particle’s internal spin transition, akin to optical dipole traps for ultracold atoms. In close analogy to optical lattices, arrays of magnetic traps, i.e. magnetic lattices, are proposed as a platform for quantum simulation of exotic Hubbard models. Furthermore, two specific implementations are discussed in detail, one based on a superconducting circuit and another one based on surface acoustic waves. [Phys. Rev. B 97, 235451] Published Fri Jun 29, 2018 J. Knörzer, M. J. A. Schuetz, G. Giedke, H. Huebl, M. Weiler, M. D. Lukin, and J. I. Cirac American Physical Society (APS) 1098-0121 10980121 1095-3795 10953795 |
| shingle_catch_all_4 | Solid-state magnetic traps and lattices Surface physics, nanoscale physics, low-dimensional systems Author(s): J. Knörzer, M. J. A. Schuetz, G. Giedke, H. Huebl, M. Weiler, M. D. Lukin, and J. I. Cirac This work examines the feasibility of magnetic traps and lattices for electrons in semiconductors. The authors provide a general theoretical framework and show that thermally stable traps can be generated by magnetically driving the particle’s internal spin transition, akin to optical dipole traps for ultracold atoms. In close analogy to optical lattices, arrays of magnetic traps, i.e. magnetic lattices, are proposed as a platform for quantum simulation of exotic Hubbard models. Furthermore, two specific implementations are discussed in detail, one based on a superconducting circuit and another one based on surface acoustic waves. [Phys. Rev. B 97, 235451] Published Fri Jun 29, 2018 J. Knörzer, M. J. A. Schuetz, G. Giedke, H. Huebl, M. Weiler, M. D. Lukin, and J. I. Cirac American Physical Society (APS) 1098-0121 10980121 1095-3795 10953795 |
| shingle_title_1 | Solid-state magnetic traps and lattices |
| shingle_title_2 | Solid-state magnetic traps and lattices |
| shingle_title_3 | Solid-state magnetic traps and lattices |
| shingle_title_4 | Solid-state magnetic traps and lattices |
| timestamp | 2025-06-30T23:35:53.093Z |
| titel | Solid-state magnetic traps and lattices |
| titel_suche | Solid-state magnetic traps and lattices |
| topic | U |
| uid | ipn_articles_6295935 |