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The Application of Modern Metallurgical Principles And Knowledge to the Manufacture of Mokumé Gane (Wood-Grain Metal) Decorative Alloy

Published online by Cambridge University Press:  01 February 2011

Ian T. Ferguson
Affiliation:
School of Materials, University of Manchester, Grosvenor Street, Manchester M1 7HD, United Kingdom.
Brian Derby
Affiliation:
School of Materials, University of Manchester, Grosvenor Street, Manchester M1 7HD, United Kingdom.
G. E. Thompson
Affiliation:
School of Materials, University of Manchester, Grosvenor Street, Manchester M1 7HD, United Kingdom.
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Abstract

Mokumé Gane layered metal is a 300-year old decorative metal laminate technique peculiar to the isolated culture of the Japanese Shogunate. Like many complex craft practices handed down through individual experience, the manufacture and development of Mokumé Gane has changed minimally over time. The application of contemporary metallurgical knowledge and solid state bonding techniques such as Hot Press Diffusion Bonding and Hot Roll Bonding provide for further development of Mokumé Gane: bonding success rates are improved, and manufacturing times are reduced. In addition, the range of possible metal combinations is substantially increased; 42 different combinations to date have been successfully bonded, including a new type of Mokumé Gane employing aluminium alloys. This research has allowed a very large increase in the variety of colours, patterns, and visual effects, available to contemporary metalsmiths and jewellers.

Type
Research Article
Copyright
Copyright © Materials Research Society 2005

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References

REFERENCES

i Roberts-Austen, W.C., “Cantor LecturesJournal of the Society of Arts, Vol. 36 pp. 1137 - 1146 (1888) and Vol.41 pp.1007 – 1043 (1893).Google Scholar
ii British Patent No. 1, 488, 984 for Clad Metals Inc.Google Scholar
iii Schwartz, M.M., Metal Joining Manual, (McGraw-Hill Book Company Inc., New York) p1054(1983).Google Scholar
iv Zanner, F.J., Fisher, R.W., “Diffusion Welding of Commercial Bronze to Titanium Alloy,” Welding Journal, Vol. 54 p111–s (April 1975).Google Scholar
v Tylecote, R.F., A History of Metallurgy (The Metals Society, London 1976).Google Scholar
vi AWS Welding Handbook; 7th Ed. Vol. 3, “Resistance and solid state welding and other joining processes” Ed. Kearns, W.H., (American Welding Society, Miami 1980) p318.Google Scholar
vii AWS Welding Handbook; 7th Ed. Vol. 3, “Resistance and solid state welding and other joining processes” Ed. Kearns, W.H., (American Welding Society, Miami 1980) p313.Google Scholar
viii Smithells Metals Reference Book 6th Ed, (Butterworth & Co., London 1983) p1113.Google Scholar
ix Vaidyanath, L.R, Milner, D.R., “Significance of Surface Preparation in Cold Pressure WeldingBritish Welding Journal, (Jan. 1960) pp.1 - 6.Google Scholar
x Ferguson, I.T., Mokumé Gane (A&C Black London, 2002)Google Scholar
xi Larke, E.C., The Rolling of Strip, Sheet and Plate (Chapman and Hall Ltd, London 1963).Google Scholar