Three-Dimensional Modeling and Measurement of Coupling AC Loss in Soldered Tapes and Striated Coated Conductors

Abstract

Coupling ac loss between superconducting filaments or tapes produces additional heating, complicating the cryogenics of superconducting applications and reducing their efficiency. Predicting the coupling currents and the loss that they generate in general 3-D samples require numerical computations. These may reduce the coupling loss by sample optimization and are necessary for the device design. In this work, we model and measure coupling (and hysteresis) loss of soldered and striated tapes. Coupling loss is measured at 72 and 144 Hz for applied fields up to 100-mT amplitude and frequencies from 2.4 to 576 Hz for applied magnetic fields around 4 mT. Modeling is based on an original variational principle. This model is also benchmarked with finite-element method computations, showing good agreement. For both models, we assume an isotropic power law relation between the electric field and the current density. We also introduce a simpler 3-D model that assumes zero resistivity in the superconductor. The latter model, together with cross-sectional methods for the hysteresis loss, is enough to satisfactorily predict the ac loss, except for applied field amplitudes above the loss factor peak and very short samples. The variational method is promising for more complicated 3-D situations.