Journal
MATERIALS & DESIGN
Volume 176, Issue -, Pages -Publisher
ELSEVIER SCI LTD
DOI: 10.1016/j.matdes.2019.107836
Keywords
Diffusion; Microstructure; Flux-pinning; Soldering; Texture
Categories
Funding
- Royal Society-SERB Newton International Fellowship
- EPSRC [EP/K040375/1, EP/N010868/1]
- EPSRC [EP/N010868/1] Funding Source: UKRI
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Interactions of superconducting Nb(47 wt% Ti) with liquid binary In-35 wt% Sn and Bi-containing ternary (In, 15 wt% Bi)-35 wt% Sn solders have been examined for the first time up to 450 degrees C. Reaction of NbTi with InSn results in an intermetallic phase, (Nb, Ti)Sn-2, the morphology and chemical composition of which depends on the size of NbTi filaments. Larger filaments react to form a thin uniform (Nb, Ti)Sn-2 phase with a Nb: Ti ratio of 6:1, while for finer filaments large (Nb, Ti)Sn-2 grains grow with a Nb: Ti ratio of 0.5: 1. Differences for interfacial phase layers have been explained by a diffusion-controlled growth model based on metallurgical state of NbTi filaments. Neither filamentary types exhibit any change in critical temperature (similar to 9.2 K) after soldering treatment at 350 degrees C, but the irreversibility field and flux line pinning force of NbTi changes by a higher factor for the larger filaments. Interaction of NbTiwith ternary (In, Bi)Sn results in a lack of any detectable interaction zone, and characteristic nucleation behaviour of phases in the bulk solder at NbTi-(In, Bi)Sn interface is rationalized on the basis of thermodynamic arguments. Transport measurements suggest that properties of solder are the limiting factor for joint behaviour and not any interfacial reactions. (c) 2019 The Authors. Published by Elsevier Ltd.
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