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Electrical conductivity in directionally solidified lead-9 and -20 wt pct copper alloys

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Abstract

Composites consisting of aligned copper dendrites in a lead matrix have been produced by directional solidification processing for potential application as grids in lead-acid batteries. To promote a uniform composite of aligned copper dendrites in a protective lead matrix, two alloy compositions, Pb-9 and -20 wt pct Cu, have been directionally solidified through a temperature gradient,G l of 4.5 Kmm-1 at constant growth velocities which ranged from 1 to 100 µm s-1. With slow growth rates (≲10 µm s-1 ), the copper dendrites were generally columnar and continuous along the sample length; at higher velocities (≳60 µm s-1), they assumed an intricate and equiaxed morphology. In accordance with copper content and growth rate, the electrical conductivity of the directionally solidified composites was found to be as much as a 2.5 times that of pure lead. The results are compared with that predicted by a model based on a geometrical dendrite.

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Authors and Affiliations

  1. Department of Materials Science and Engineering, Vanderbilt University, 37235, Nashville, TN

    W. F. Flanagan (Professor of Materials Science and Engineering), B. D. Lichter (Professor of Materials Science and Engineering) & R. N. Grugel (Research Associate Professor, Center for Microgravity Research and Applications)

  2. Seoul, Korea

    Shinwoo Kim

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  1. Shinwoo Kim
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  2. W. F. Flanagan
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  3. B. D. Lichter
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  4. R. N. Grugel
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Additional information

Formerly Doctoral Student, Department of Materials Science and Engineering, Vanderbilt University.Seoul Korea.

This paper is based on work leading to the successful completion of his Ph.D. degree at Vanderbilt University.

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Kim, S., Flanagan, W.F., Lichter, B.D. et al. Electrical conductivity in directionally solidified lead-9 and -20 wt pct copper alloys. Metall Trans A 24, 975–979 (1993). https://doi.org/10.1007/BF02656519

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  • DOI: https://doi.org/10.1007/BF02656519

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