High-Energy, High-Rate Materials Processing
High-energy, high-rate processing, driven by fast discharging stored energy devices, offers new potential for producing materials that are otherwise difficult to create, and for the secondary processing of materials such as those derived from the rapid solidification technologies
Feature Process Technology
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Keywords
Metallic Glass Metal Matrix Composite Boron Carbide Specific Energy Input Pure Tungsten
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.
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References
- 1.W.F. Weldon, IEEE Spectrum, 22, No. 3 (1985), p. 59.Google Scholar
- 2.G.B. Grant, W.M. Featherston, R.E. Keith, W.F. Weldon, H.G. Rylander and H.H. Woodson, Welding Journal, 58 (1979), pp. 24–26.Google Scholar
- 3.J.B. Walters and T A. Aanstoos, Metal Progress, April (1985), p. 25.Google Scholar
- 4.S.K. Das and D. Raybould, Fifth Int. Conf. on Rapidly Quenched Metals, Paper N67, Wurzburg, Germany. September, 1984.Google Scholar
- 5.C. Persad and D.R. Peterson, IEEE Trans on Magnetics, Vol. 22, November 1986, pp. 1658–1661.CrossRefGoogle Scholar
- 6.D.R. Ervin, D.L. Bourell, C. Persad and L. Rabenberg, Journal of Materials Science and Engineering, in press.Google Scholar
- 7.K.C. Owen, M J. Wang, C. Persad and Z. Eliezer, Wear, 120, No. 1 (1987), p. 177.CrossRefGoogle Scholar
- 8.H.L. Marcus, L. Rabenberg, L.D. Brown, G. Elkabir and Y.M. Cheong, ICCM VI/ECCM 2, ed. F.L. Matthews et al., Elsevier Applied Science Publisher, Ltd., London, 1987, p. 2.459.Google Scholar
- 9.C J. Lund, C. Persad and Z. Eliezer, Wear, No. 2 (1987), p. 251.CrossRefGoogle Scholar
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© TMS 1987