AC loss and coupling currents in YBCO coated conductors with varying number of filaments

TL;DR

This study demonstrates that striating YBCO coated conductors into many filaments significantly reduces AC losses while maintaining most of their current capacity, with detailed analysis of coupling currents and oxidation effects.

Contribution

It shows how to produce high-quality, highly-filamented coated conductors that greatly reduce AC losses without severely impairing their transport properties, and offers new insights into coupling current pathways.

Findings

AC loss reduction exceeds one order of magnitude.

Samples with 10 and 20 filaments retain full current capacity.

Coupling currents mainly flow in the metallic substrate.

Abstract

Striation of HTS coated conductors (CCs) as a way to reduce their magnetization AC losses has been the subject of intense research in the past years by several groups. While the principle of this approach is well understood, its practical application on commercial material to be used in power application is still far to be implemented due to manufacturing and technological constraints. Recent advances in tape quality and striation technology are now enabling systematic investigations of the influence of the number of filaments on AC loss reduction with a consistency that was not available in the past. In this work we demonstrate the technological feasibility of reducing the magnetization losses of commercially available CC by striating them into a high number of filaments (up to 120). The loss reduction exceeds one order of magnitude and does not come at the expense of current-carrying capability: samples with 10 and 20 filaments are unaffected by the striation process, while samples with 80 and 120 filaments still retain 80 and 70% of the current-carrying potential, respectively. We also investigate the transverse resistivity in order to understand the paths followed by the coupling currents: we found that the coupling current prevalently flows in the metallic substrate, rather than in and out of the filaments. Finally, we use oxidation as a method to reduce the coupling currents and losses. The contribution of this work is three-fold: 1) It describes the know-how to produce a large number of high quality striations in commercially available CCs, greatly reducing their losses without extensively degrading their transport properties; 2) It provides a comprehensive characterization of said samples (e.g. measurements in a wide frequency range, transverse resistance profiles, influence of oxidation on DC and AC behavior); 3) It provides new insight on the patterns of the coupling currents.