Superconducting rf cavities are increasingly used in accelerators. Gradient is a parameter of particular importance for the ILC. Much progress in gradient has been made over the past decade, overcoming problems of multipacting, field emission, and breakdown triggered by surface impurities. However, the quenching limit of the surface magnetic field for niobium remains a hard limitation on cavity fields sustainable with this technology. Further exploration of materials and preparation may offer a path to surpassing the current limit. For this purpose, we have designed a resonant test cavity. One wall of the cavity is formed by a flat sample of superconducting material; the rest of the cavity is copper or niobium. The H field on the sample wall is 75% higher than on any other surface. Multipacting is avoided by use of a mode with no surface electric field. The cavity will be resonated through a coupling iris with high-power rf at superconducting temperature until the sample wall quenches, as detected by a change in the quality factor. This experiment will allow us to measure critical magnetic fields up to well above that of niobium with minimal cost and effort.
[1]
H. Edwards.
RF superconductivity: enabling technology for the future
,
2003,
Proceedings of the 2003 Particle Accelerator Conference.
[2]
Hasan Padamsee,et al.
An optimized shape cavity for TESLA: concept and fabrication
,
2003,
Proceedings of the 2003 Particle Accelerator Conference.
[3]
Darko Kajfez,et al.
Random and systematic uncertainties of reflection-type Q-factor measurement with network analyzer
,
2003
.
[4]
D. Pritzkau.
RF pulsed heating
,
2001
.
[5]
E. al.,et al.
Superconducting TESLA cavities
,
2000,
physics/0003011.