Synchrotron Microtomography Investigation of the Filament Microstructure in Differently Processed Bi-2212 Wires

The Bi-2212 microstructure and porosity distribution in entire state-of-the-art multifilament wires was characterized by high-energy synchrotron X-ray absorption microtomography after meltprocessing at ambient pressure, at 100 bar overpressure, and at ambient pressure after prior cold isostatic pres...

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Veröffentlicht in:	IEEE Trans.Appl.Supercond 2017-06, Vol.27 (4), p.1-5
Hauptverfasser:	Scheuerlein, Christian, Rack, Alexander, Schladitz, Katja, Huwig, Luisa
Format:	Artikel
Sprache:	eng
Schlagworte:	Bars Bi-2212 finite percolation probabilities Image reconstruction Image segmentation Instrumentation and Detectors Integrated circuits micro-structure micro-tomography Microstructure Physics synchrotron Synchrotrons Wires
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creator	Scheuerlein, Christian Rack, Alexander Schladitz, Katja Huwig, Luisa
description	The Bi-2212 microstructure and porosity distribution in entire state-of-the-art multifilament wires was characterized by high-energy synchrotron X-ray absorption microtomography after meltprocessing at ambient pressure, at 100 bar overpressure, and at ambient pressure after prior cold isostatic pressing of initially identical as-drawn wires. Beyond the visualization of the Bi-2212 microstructure, the porosity distribution in the different filament bundles has been quantified. Spherical granulometry and finite percolation probability calculations have been performed in order to provide a measure for the porosity distribution and to compare filament connectivity in the axial wire direction. Possible artifacts of the microtomography (μ-CT) experiment and the possibility to estimate the effect of the Bi-2212 microstructure as seen in the μ-CT images on critical current density are discussed.
doi_str_mv	10.1109/TASC.2016.2644539
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Beyond the visualization of the Bi-2212 microstructure, the porosity distribution in the different filament bundles has been quantified. Spherical granulometry and finite percolation probability calculations have been performed in order to provide a measure for the porosity distribution and to compare filament connectivity in the axial wire direction. 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Beyond the visualization of the Bi-2212 microstructure, the porosity distribution in the different filament bundles has been quantified. Spherical granulometry and finite percolation probability calculations have been performed in order to provide a measure for the porosity distribution and to compare filament connectivity in the axial wire direction. 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subjects	Bars Bi-2212 finite percolation probabilities Image reconstruction Image segmentation Instrumentation and Detectors Integrated circuits micro-structure micro-tomography Microstructure Physics synchrotron Synchrotrons Wires
title	Synchrotron Microtomography Investigation of the Filament Microstructure in Differently Processed Bi-2212 Wires
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