Shortcuts to adiabaticity: Concepts, methods, and applications

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dc.contributor.author Guéry-Odelin, D.
dc.contributor.author Ruschhaupt, A.
dc.contributor.author Kiely, A.
dc.contributor.author Torrontegui Muñoz, Erik
dc.contributor.author Martínez Garaot, S.
dc.contributor.author Muga, J. G.
dc.date.accessioned 2021-02-23T11:14:46Z
dc.date.available 2021-02-23T11:14:46Z
dc.date.issued 2019-10-24
dc.identifier.bibliographicCitation D. Guéry-Odelin, Ruschhaupt, A., Kiely, A., Torrontegui, E., Martínez Garaot, S. y Muga, J. G. (2019). Shortcuts to adiabaticity: Concepts, methods, and applications. Reviews of Modern Physics, 91, 045001.
dc.identifier.issn 0034-6861
dc.identifier.uri http://hdl.handle.net/10016/31999
dc.description.abstract Shortcuts to adiabaticity (STA) are fast routes to the final results of slow, adiabatic changes of the controlling parameters of a system. The shortcuts are designed by a set of analytical and numerical methods suitable for different systems and conditions. A motivation to apply STA methods to quantum systems is to manipulate them on timescales shorter than decoherence times. Thus shortcuts to adiabaticity have become instrumental in preparing and driving internal and motional states in atomic, molecular, and solid-state physics. Applications range from information transfer and processing based on gates or analog paradigms to interferometry and metrology. The multiplicity of STA paths for the controlling parameters may be used to enhance robustness versus noise and perturbations or to optimize relevant variables. Since adiabaticity is a widespread phenomenon, STA methods also extended beyond the quantum world to optical devices, classical mechanical systems, and statistical physics. Shortcuts to adiabaticity combine well with other concepts and techniques, in particular, with optimal control theory, and pose fundamental scientific and engineering questions such as finding speed limits, quantifying the third law, or determining process energy costs and efficiencies. Concepts, methods, and applications of shortcuts to adiabaticity are reviewed and promising prospects are outlined, as well as open questions and challenges ahead.
dc.description.sponsorship We thank P. Claeys, S. Deffner, C. Jarzynski, R. Kosloff, M. Sarandy, E. Sherman, D. Sugny, K. Takahashi, E. Trizac, and S.-Y. Tseng for clarifying comments or a critical reading of the manuscript or sections of it. Many colleagues and collaborators, too numerous to mention individually, have contributed through the last 10 years to our work on shortcuts. We are deeply indebted to all of them. This work was supported by the Basque Country Government (Grant No. IT986-16); PGC2018-101355-B-100 (MCIU/AEI/FEDER, UE); PGC2018-094792-B-100 (MCIU/AEI/FEDER, EU); CAM/FEDER Project No. S2018/TCS-4342 (QUITEMAD-CM); and by Programme Investissements d’Avenir under the Grant ANR-11-IDEX-0002-02, reference ANR-10-LABX-0037-NEXT, as well as the Grant ANR-18-CE30-0013.
dc.format.extent 54
dc.language.iso eng
dc.publisher American Physical Society
dc.rights © 2019 American Physical Society.
dc.title Shortcuts to adiabaticity: Concepts, methods, and applications
dc.type article
dc.subject.eciencia Física
dc.identifier.doi https://doi.org/10.1103/RevModPhys.91.045001
dc.rights.accessRights openAccess
dc.relation.projectID Comunidad de Madrid. S2018/TCS-4342
dc.type.version acceptedVersion
dc.identifier.publicationissue 4
dc.identifier.publicationtitle Reviews of Modern Physics
dc.identifier.publicationvolume 91
dc.identifier.uxxi AR/0000025927
dc.contributor.funder Comunidad de Madrid
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