Feasibility Study for an EDM Storage Ring

F. Abusaif; A. Aggarwal; A. Aksentev; B. Alberdi-Esuain; L. Barion; S.; Basile; M. Berz; M. Bey{\ss}; C. B\"ohme; J. B\"oker; J. Borburgh; C. Carli,; I. Ciepa{\l}; G. Ciullo; M. Contalbrigo; J.-M. De Conto; S. Dymov; R. Engels,; O. Felden; M. Gagoshidze; M. Gaisser; R. Gebel; N. Giese; K. Grigoryev; D.; Grzonka; T. Hanraths; C. Hanhart; D. Heberling; V. Hejny; J. Hetzel; D.; H\"olscher; O. Javakhishvili; A. Kacharava; S. Karanth; C. K\"aseberg; V.; Kamerdzhiev; I. Keshelashvili; I. Koop; A. Kulikov; K. Laihem; M. Lamont; A.; Lehrach; P. Lenisa; N. Lomidze; B. Lorentz; G. Macharashvili; A. Magiera; R.; Maier; K. Makino; S. Martin; D. Mchedlishvili; U.-G. Mei{\ss}ner; Z.; Metreveli; J. Michaud; F. M\"uller; A. Nass; G. Natour; N. Nikolaev; A.; Nogga; A. Pesce; V. Poncza; D. Prasuhn; J. Pretz; F. Rathmann; J. Ritman; M.; Rosenthal; A. Saleev; M. Schott; T. Sefzick; Y. Senichev; D. Shergelashvili,; V. Shmakova; S. Siddique; A. Silenko; M. Simon; J. Slim; H. Soltner; A.; Stahl; R. Stassen; E. Stephenson; H. Straatmann; H. Str\"oher; M. Tabidze; G.; Tagliente; M. Tahar; R. Talman; Yu. Uzikov; Yu. Valdau; E. Valetov; T.; Wagner; C. Weidemann; C. Wilkin; A. Wirzba; A. Wro\'nska; and P. W\"ustner

arXiv:1812.08535·physics.acc-ph·January 21, 2019·6 cites

Feasibility Study for an EDM Storage Ring

F. Abusaif, A. Aggarwal, A. Aksentev, B. Alberdi-Esuain, L. Barion, S., Basile, M. Berz, M. Bey{\ss}, C. B\"ohme, J. B\"oker, J. Borburgh, C. Carli,, I. Ciepa{\l}, G. Ciullo, M. Contalbrigo, J.-M. De Conto, S. Dymov, R. Engels,, O. Felden, M. Gagoshidze, M. Gaisser, R. Gebel

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TL;DR

This study explores the feasibility of using a specialized storage ring to detect electric dipole moments in charged particles, aiming for extremely sensitive measurements with minimized systematic errors.

Contribution

It proposes a step-wise experimental plan, demonstrating technical feasibility and developing key technologies for high-precision EDM measurements in storage rings.

Findings

01

Reduced polarization measurement errors

02

Long horizontal-plane polarization lifetimes

03

Control of polarization direction through feedback

Abstract

This project exploits charged particles confined as a storage ring beam (proton, deuteron, possibly $^{3}$ He) to search for an intrinsic electric dipole moment (EDM, $d$ ) aligned along the particle spin axis. Statistical sensitivities can approach $1 0^{- 29}$ ~e $\cdot$ cm. The challenge will be to reduce systematic errors to similar levels. The ring will be adjusted to preserve the spin polarization, initially parallel to the particle velocity, for times in excess of 15 minutes. Large radial electric fields, acting through the EDM, will rotate the polarization ( $d \times E$ ). The slow rise in the vertical polarization component, detected through scattering from a target, signals the EDM. The project strategy is outlined. It foresees a step-wise plan, starting with ongoing COSY activities that demonstrate technical feasibility. Achievements to date include reduced polarization…

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Taxonomy

TopicsComputational Physics and Python Applications · Geophysical and Geoelectrical Methods · Magnetic confinement fusion research