CERN Accelerating science

If you experience any problem watching the video, click the download button below
Download Embed
Preprint
Report number arXiv:2204.01178 ; FERMILAB-PUB-22-241-SQMS-TD
Title Key directions for research and development of superconducting radio frequency cavities
Author(s) Belomestnykh, S. (Fermilab ; Stony Brook U.) ; Posen, S. (Fermilab) ; Bafia, D. (Fermilab) ; Balachandran, S. (Natl. High Mag. Field Lab.) ; Bertucci, M. (LASA, Segrate) ; Burrill, A. (SLAC) ; Cano, A. (Fermilab) ; Checchin, M. (Fermilab) ; Ciovati, G. (Jefferson Lab) ; Cooley, L.D. (Natl. High Mag. Field Lab.) ; Semione, G. Dalla Lana (Hamburg U.) ; Delayen, J. (Old Dominion U. ; Jefferson Lab) ; Eremeev, G. (Fermilab) ; Furuta, F. (Fermilab) ; Gerigk, F. (CERN) ; Giaccone, B. (Fermilab) ; Gonnella, D. (SLAC) ; Grassellino, A. (Fermilab) ; Gurevich, A. (Old Dominion U.) ; Hillert, W. (Hamburg U.) ; Iavarone, M. (Temple U.) ; Knobloch, J. (Helmholtz-Zentrum, Berlin ; Siegen U.) ; Kubo, T. (KEK, Tsukuba ; Sokendai, Kanagawa) ; Kwok, W.-K. (Argonne) ; Laxdal, R. (TRIUMF) ; Lee, P.J. (Natl. High Mag. Field Lab.) ; Liepe, M. (Cornell U.) ; Martinello, M. (Fermilab) ; Melnychuk, O.S. (Fermilab) ; Nassiri, A. (Argonne) ; Netepenko, A. (Fermilab) ; Padamsee, H. (Cornell U. ; Fermilab) ; Pagani, C. (LASA, Segrate) ; Paparella, R. (LASA, Segrate) ; Pudasaini, U. (Jefferson Lab) ; Reece, C.E. (Jefferson Lab) ; Reschke, D. (DESY) ; Romanenko, A. (Fermilab) ; Ross, M. (SLAC) ; Saito, K. (Michigan State U.) ; Sauls, J. (Northwestern U.) ; Seidman, D.N. (Northwestern U.) ; Solyak, N. (Fermilab) ; Sung, Z. (Fermilab) ; Umemori, K. (KEK, Tsukuba) ; Valente-Feliciano, A.-M. (Jefferson Lab) ; Delsolaro Venturini, W. (CERN) ; Walker, N. (DESY) ; Weise, H. (DESY) ; Welp, U. (Argonne) ; Wenskat, M. (Hamburg U.) ; Wu, G. (Fermilab) ; Xi, X.X. (Temple U.) ; Yakovlev, V. (Fermilab) ; Yamamoto, A. (KEK, Tsukuba ; CERN) ; Zasadzinski, J. (IIT, Chicago)
Imprint 2022-04-03
Note contribution to Snowmass 2021
Presented at 2021 Snowmass Summer Study, Seattle, WA, United States, 11 - 20 July 2021, pp.
Subject category physics.acc-ph ; Accelerators and Storage Rings
Abstract Radio frequency superconductivity is a cornerstone technology for many future HEP particle accelerators and experiments from colliders to proton drivers for neutrino facilities to searches for dark matter. While the performance of superconducting RF (SRF) cavities has improved significantly over the last decades, and the SRF technology has enabled new applications, the proposed HEP facilities and experiments pose new challenges. To address these challenges, the field continues to generate new ideas and there seems to be a vast room for improvements. In this paper we discuss the key research directions that are aligned with and address the future HEP needs.
Other source Inspire
Copyright/License preprint: (License: CC BY 4.0)



 
 Δημιουργία εγγραφής 2022-04-28, τελευταία τροποποίηση 2024-12-04


Πλήρες κείμενο:
2204.01178 - Κατέβασμα πλήρες κειμένουPDF
jt - Κατέβασμα πλήρες κειμένουPDF
εξωτερικοί σύνδεσμοι:
Κατέβασμα πλήρες κειμένουFermilab Library Server
Κατέβασμα πλήρες κειμένουeConf