An optimized shape cavity for TESLA: concept and fabrication

Author

Shemelin, V. ; Geng, R.L. ; Kirchgessner, J. ; Padamsee, H. ; Sears, J.

Author_Institution

Lab. for Elementary-Particle Phys., Cornell Univ., Ithaca, NY, USA

Volume

2

fYear

2003

fDate

12-16 May 2003

Firstpage

1314

Abstract

The accelerating gradient performance of superconducting niobium cavities is rapidly progressing as a result of reduced field emission due to improvement in surface preparation techniques. Beyond the field emission limitation, there exists a fundamental limit imposed by the critical magnetic field of niobium. One way to tackle this limit is to reduce the ratio of the peak magnetic field to the accelerating gradient so that a higher accelerating gradient is possible while the cavity is still superconducting. New cavity shapes of reentrant type have been proposed and optimized. A single cell 1300 MHz cavity of this new class of shapes has been fabricated. Because of the reentrant geometry, the fabrication and surface cleaning of the cavity becomes challenging. In this paper, we present some calculation prerequisites and the fabrication and preparation results for this new cavity.

Keywords

accelerator cavities; beam handling techniques; electron accelerators; linear accelerators; superconducting cavity resonators; 1300 MHz; TESLA; accelerating gradient; cavity fabrication; cavity surface cleaning; critical magnetic field; field emission; optimized shape cavity; peak magnetic field; reentrant geometry; single cell cavity; superconducting niobium cavities; surface preparation techniques; Acceleration; Fabrication; Geometry; Laboratories; Magnetic fields; Niobium; Shape; Superconducting magnets; Surface cleaning; Surface waves;

fLanguage

English

Publisher

ieee

Conference_Titel

Particle Accelerator Conference, 2003. PAC 2003. Proceedings of the

ISSN

1063-3928

Print_ISBN

0-7803-7738-9

Type

conf

DOI

10.1109/PAC.2003.1289690

Filename

1289690