Abstract
The high transition temperature and low surface resistance of MgB2 attracts interest in its potential application in superconducting radio frequency accelerating cavities. However, compared to traditional Nb cavities, the viability of MgB2 at high rf fields is still open to question. Our approach is to study the nonlinear electrodynamics of the material under localized rf magnetic fields. Because of the presence of the small superconducting gap in the $\pi$ band, the nonlinear response of MgB2 at low temperature is potentially complicated compared to a single-gap s-wave superconductor such as Nb. Understanding the mechanisms of nonlinearity coming from the two-band structure of MgB2, as well as extrinsic sources of nonlinearity, is an urgent requirement. A localized and strong rf magnetic field, created by a magnetic write head, is integrated into our nonlinear-Meissner-effect scanning microwave microscope [Tamin Tai, X. X. Xi, C. G. Zhuang, D. I. Mircea, and S. M. Anlage, IEEE Trans. Appl. Supercond. 21, 2615 (2011)]. MgB2 films with thickness 50 nm, fabricated by a hybrid physical-chemical vapor deposition technique on dielectric substrates, are measured at a fixed location and show a strongly temperature-dependent third harmonic response. We propose that several possible mechanisms are responsible for this nonlinear response.
Highlights
The discovery of superconductivity in MgB2 in January 2001 [1] ignited enthusiasm and interest in exploring its material properties
Our approach is to study the nonlinear electrodynamics of the material under localized rf magnetic fields
The success of making high quality epitaxial MgB2 thin films provides another promising application as an alternative material coating on superconducting radio frequency (SRF) cavities [2]
Summary
The discovery of superconductivity in MgB2 in January 2001 [1] ignited enthusiasm and interest in exploring its material properties. The success of making high quality epitaxial MgB2 thin films provides another promising application as an alternative material coating on superconducting radio frequency (SRF) cavities [2]. The intrinsic nonlinear response of MgB2 at low temperature is large compared to single-gap s-wave superconductors [6,7]. If MgB2 is a nodal superconductor, the coating of MgB2 on SRF cavities will limit the high-field screening response at low temperature and degrade the performance of the SRF cavities. MgB2 microwave nonlinear response in the high frequency region (usually several GHz in SRF applications) can reveal the dissipative and nondissipative nonlinear mechanisms and perhaps enable application of MgB2 films as cavity coatings. These data will be interpreted as a combination of several nonlinear mechanisms including intrinsic nonlinear responses [7,8] and vortex nonlinearity [5]
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