Temperature dependence of the superheating field in niobium

TL;DR

This paper experimentally studies how the superheating field of niobium varies with temperature, using high power pulses to understand limits in superconducting cavities for particle accelerators.

Contribution

It provides an experimental method to measure the temperature dependence of the superheating field and examines the impact of heat treatments on this fundamental limit.

Findings

Superheating field decreases with increasing temperature.

110-120°C heat treatment reduces the superheating field.

Transition to normal state is global, indicating a fundamental limit.

Abstract

This study experimentally investigates the temperature dependence of superheating field, Hsh, of niobium. Accurately determining this field is important both to test theory and to understand gradient limits in superconducting cavities for particle accelerators. This paper discusses theories that have been proposed in modeling the field and discriminates between them. The experimental procedure for measuring the temperature dependence of Hsh utilizes high power pulses to drive a niobium cavity resonator, ramping up surface magnetic fields extremely quickly. The moment any part of the cavity transitions between the superconducting and normal conducting state can be determined by measuring the quality factor of the cavity as a function of time. Oscillating superleak transducers are used to demonstrate that the transition to the normal conducting state is global in nature, showing that a fundamental limit is encountered. Finally, we see that 110-120 C heat treatment of the cavity--a method commonly used to increase the quality factor at high accelerating gradients--may have the deleterious effect of reducing the superheating field of the material, which is the fundamental limiting factor in pursuing the maximal achievable accelerating gradient in superconducting niobium cavities.