CUED Publications database

Numerical modelling of iron-pnictide bulk superconductor magnetization

Ainslie, MD and Yamamoto, A and Fujishiro, H and Weiss, JD and Hellstrom, EE (2017) Numerical modelling of iron-pnictide bulk superconductor magnetization. SUPERCONDUCTOR SCIENCE & TECHNOLOGY, 30. ISSN 0953-2048

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Abstract

The iron-based superconductors exhibit a number of properties attractive for applications, including low anisotropy, high upper critical magnetic fields (Hc2) in excess of 90 T and intrinsic critical current densities above 1 MA/cm2 (0 T, 4.2 K). It was shown recently that bulk iron-pnictide superconducting magnets capable of trapping over 1 T (5 K) and 0.5 T (20 K) can be fabricated with fine-grain polycrystalline Ba0.6K0.4Fe2As2 (Ba122). These Ba122 magnets were processed by a scalable, versatile and low-cost method using common industrial ceramic processing techniques. In this paper, a standard numerical modelling technique, based on a 2D axisymmetric finite-element model implementing the H-formulation, is used to investigate the magnetisation properties of such iron-pnictide bulk superconductors. Using the measured Jc(B, T) characteristics of a small specimen taken from a bulk Ba122 sample, experimentally measured trapped fields are reproduced well for a single bulk, as well as a stack of bulks. Additionally, the influence of the geometric dimensions (thickness and diameter) on the trapped field is analysed, with a view of fabricating larger samples to increase the magnetic field available from such TFMs. It is shown that, with current state-of-the-art superconducting properties, surface trapped fields > 2 T could readily be achieved at 5 K (and > 1 T at 20 K) with a sample of diameter 50 mm. Finally, an aspect ratio of between 1-1.5 for R/H (radius/thickness) would be an appropriate compromise between the accessible, surface trapped field and volume of superconducting material for bulk Ba122 magnets.

Item Type: Article
Uncontrolled Keywords: bulk superconductors critical current density (superconductivity) finite-element method iron pnictides numerical simulation trapped field magnets
Subjects: UNSPECIFIED
Divisions: Div C > Materials Engineering
Depositing User: Cron Job
Date Deposited: 07 Aug 2017 20:05
Last Modified: 26 Oct 2017 01:47
DOI: