Scaling laws for the depolarization time of relativistic particle beams in strong fields

Scaling laws for the depolarization time of relativistic particle beams in strong fields

The acceleration of polarized electrons and protons in strong laser and plasma fields is a very attractive option to obtain polarized beams in the GeV range. We investigate the feasibility of particle acceleration in strong fields without destroying an initial polarization, taking into account all r...

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Main Authors: Johannes Thomas, Anna Hützen, Andreas Lehrach, Alexander Pukhov, Liangliang Ji, Yitong Wu, Xuesong Geng, Markus Büscher
Format: Article
Language:English
Published: American Physical Society 2020-06-01
Series:Physical Review Accelerators and Beams
Online Access:http://doi.org/10.1103/PhysRevAccelBeams.23.064401
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spelling doaj-e7eececd645541a9a1ebd4d2e322262c2020-11-25T03:18:12ZengAmerican Physical SocietyPhysical Review Accelerators and Beams2469-98882020-06-0123606440110.1103/PhysRevAccelBeams.23.064401Scaling laws for the depolarization time of relativistic particle beams in strong fieldsJohannes ThomasAnna HützenAndreas LehrachAlexander PukhovLiangliang JiYitong WuXuesong GengMarkus BüscherThe acceleration of polarized electrons and protons in strong laser and plasma fields is a very attractive option to obtain polarized beams in the GeV range. We investigate the feasibility of particle acceleration in strong fields without destroying an initial polarization, taking into account all relevant mechanisms that could cause polarization losses, i.e. the spin precession described by the T-BMT equation, the Sokolov-Ternov effect and the Stern-Gerlach force. Scaling laws for the (de-)polarization time caused by these effects reveal that the dominant polarization limiting effect is the rotation of the single particle spins around the local electromagnetic fields. We compare our findings to test-particle simulations for high energetic electrons moving in a homogeneous electric field. For high particle energies the observed depolarization times are in good agreement with the analytically estimated ones.http://doi.org/10.1103/PhysRevAccelBeams.23.064401
collection DOAJ
language English
format Article
sources DOAJ
author Johannes Thomas
Anna Hützen
Andreas Lehrach
Alexander Pukhov
Liangliang Ji
Yitong Wu
Xuesong Geng
Markus Büscher
spellingShingle Johannes Thomas
Anna Hützen
Andreas Lehrach
Alexander Pukhov
Liangliang Ji
Yitong Wu
Xuesong Geng
Markus Büscher
Scaling laws for the depolarization time of relativistic particle beams in strong fields
Physical Review Accelerators and Beams
author_facet Johannes Thomas
Anna Hützen
Andreas Lehrach
Alexander Pukhov
Liangliang Ji
Yitong Wu
Xuesong Geng
Markus Büscher
author_sort Johannes Thomas
title Scaling laws for the depolarization time of relativistic particle beams in strong fields
title_short Scaling laws for the depolarization time of relativistic particle beams in strong fields
title_full Scaling laws for the depolarization time of relativistic particle beams in strong fields
title_fullStr Scaling laws for the depolarization time of relativistic particle beams in strong fields
title_full_unstemmed Scaling laws for the depolarization time of relativistic particle beams in strong fields
title_sort scaling laws for the depolarization time of relativistic particle beams in strong fields
publisher American Physical Society
series Physical Review Accelerators and Beams
issn 2469-9888
publishDate 2020-06-01
description The acceleration of polarized electrons and protons in strong laser and plasma fields is a very attractive option to obtain polarized beams in the GeV range. We investigate the feasibility of particle acceleration in strong fields without destroying an initial polarization, taking into account all relevant mechanisms that could cause polarization losses, i.e. the spin precession described by the T-BMT equation, the Sokolov-Ternov effect and the Stern-Gerlach force. Scaling laws for the (de-)polarization time caused by these effects reveal that the dominant polarization limiting effect is the rotation of the single particle spins around the local electromagnetic fields. We compare our findings to test-particle simulations for high energetic electrons moving in a homogeneous electric field. For high particle energies the observed depolarization times are in good agreement with the analytically estimated ones.
url http://doi.org/10.1103/PhysRevAccelBeams.23.064401
work_keys_str_mv AT johannesthomas scalinglawsforthedepolarizationtimeofrelativisticparticlebeamsinstrongfields
AT annahutzen scalinglawsforthedepolarizationtimeofrelativisticparticlebeamsinstrongfields
AT andreaslehrach scalinglawsforthedepolarizationtimeofrelativisticparticlebeamsinstrongfields
AT alexanderpukhov scalinglawsforthedepolarizationtimeofrelativisticparticlebeamsinstrongfields
AT liangliangji scalinglawsforthedepolarizationtimeofrelativisticparticlebeamsinstrongfields
AT yitongwu scalinglawsforthedepolarizationtimeofrelativisticparticlebeamsinstrongfields
AT xuesonggeng scalinglawsforthedepolarizationtimeofrelativisticparticlebeamsinstrongfields
AT markusbuscher scalinglawsforthedepolarizationtimeofrelativisticparticlebeamsinstrongfields
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