SIMULATION OF OFF-AXIS INJECTION FOR THE SYLA STORAGE RING

Within the framework of the Federal Scientific and Technical Program for the Development of Synchrotron and Neutron Research and Research Infrastructure, a fourth-generation synchrotron light source is under development at the National Research Center Kurchatov Institute. The source involves a 6 GeV storage ring and a free electron laser based on a normal conducting linear accelerator, which will also be used as an injector for the storage ring. An injection system is one of the main parts of the storage ring, which ensures the injection of electron bunches into the synchrotron. The injection system should have a high injection efficiency, hold a high beam quality, minimize the space required to accommodate its components, and ensure repeatability of the parameters of its magnetic elements. The injection of 6-GeV electrons imposes stringent requirements on pulsed kicker magnets because of the short pulse duration (~3 μs) of the high voltage supply. The multiturn horizontal injection has been simulated using an injection system consisting of a septum and four kicker magnets.

1. Ковальчук М.В. и др. // Кристаллография. 2022. Т. 67 (5). С. 726–734.

2. Polozov S.M., Kliuchevskaia Y.D., Ashanin I.A. // Abstr. LXXII Int. Conf. NUCLEUS-22. 2022. P. 344.

3. Gavrish Y. // Abstr. Conf. RuPAC’23. 2023. P. 164.

4. Дюбков В.С. // Ядерн. физ. инжинир. 2024. Т. 15 (5).

5. С. 464 [Dyubkov V.S. // Phys. At. Nucl. 2023. V. 86 (12). P. 2703].

6. Liuzzo S.M. et al. // Proc. IPAC’21. Campinas, Brazil. 2021. P. 1462.

7. Rogers W. et al. // Proc. IPAC’17. Copenhagen, Danmark. 2017. P. 3855.

8. Borland M. // Proc. ICAP-2000. 2000. LS-287. P. 11.

9. EBS Storage Ring Technical Report. https://www.esrf.fr.

10. Owen H.L., Smith S.L. // Proc. EPAC'96. Sitges, Spain. 1996. P. 2400. https://accelconf.web.cern.ch/e96/papers/mopl/mop040l.pdf.

11. Zhang S. // Proc. PAC’09. Vancouver, Canada. 2009. P. 2324.

12. Акимов А.В. и др. Технологическая инфраструктура “СКИФ”. 2021. Новосибирск: Институт катализа СО РАН. Т. 2. С. 74–82.

13. Karantzoulis E. et al. // Nucl. Instrum. Methods Phys. Res., Sect. A. 2024. V. 1060. P. 169007.

14. Leemann S.C. // Phys. Rev. ST Accel. Beams. 2012. V. 15. P. 050705.

15. Harada K. et al. // Phys. Rev. ST Accel. Beams. 2007. V. 10. P. 123501.

16. Takaki H. et al. // Phys. Rev. ST Accel. Beams. 2010. V. 13. P. 020705.

17. Atkinson T. et al. // Proc. IPAC’11. San Sebastian, Spain. 2011. P. 3394.

18. Rodrigues A.R.D. et al. // Proc. IPAC’18. Vancouver, Canada. 2018. P. 2886.

19. Quentino J.V., Alves M.B., de Sá F.H. // Proc. IPAC’22. Bangkok, Thailand. 2022. P. 2722.

20. Resende X.R. et al. // Proc. IPAC’22. Bangkok, Thailand. 2022. P. 2672.

21. Conte M., MacKay W.W. An Introduction to the Physics of Particle Accelerators. 2nd Ed. 2008. Singapore: World Scientific.

22. Wille K. The Physics of Particle Accelerators: An Introduction. 2009. Oxford: Oxford Univ. Press. 2009.

23. Wiedemann H. Particle Accelerator Physics. 4th Ed. 2019. Cham: Springer.

24. Lee S.Y. Accelerator Physics. 4th Ed. 2021. Singapore: World Scientific.