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Abstract

The age-hardening mechanism of a commercial dental gold alloy containing platinum and palladium (in wt.%, 15 Cu, 6 Ag, 5 Pt, 3 Pd, 3 Zn, with the balance as gold) was elucidated by means of electrical resistivity, hardness tests, x-ray and electron diffraction and electron microscopy, as well as high-resolution electron microscopy. The sequence of phase transformations during isothermal aging below the critical temperature, Tc = 825 K, was described as follows: disordered solid solution α₀ (FCC) → metastable AuCu I' ordered phase (FCT) → metastable α₂ disordered phase (FCC) equilibrium AuCu I ordered phase (FCT) + equilibrium α₂ disordered phase (FCC). The hardening was due to the introduction of coherency strain at the interface between the AuCu I' platelet and the matrix. These ordered platelets had mutually perpendicular c-axes to compensate for the strain introduced by their tetragonality. A loss of coherency at the interface brought about softening of the alloy, i.e., over-aging.

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References

Hirsch, P.B. ; Howie, A. ; Nicholson, R.B. ; Pashley, D.W. ; and Whelan, M.J. (1971): Electron Microscopy of Thin Crystals, London: Butterworth, pp. 317-352.

Hisatsune, K. ; Ohta, M. ; Shiraishi, T. ; and Yamane, M. (1982): Aging Reactions in a Low Gold, White Dental Alloy , J Dent Res 61:805-807.

Kanzawa, K. ; Yasuda, K. ; and Metahi, H. (1975): Structural Changes Caused by Age-Hardening in a Dental Gold Alloy, J Less-Comm Met 43:121-128.

Nicholson, R.B. and Nutting, J. (1958): Direct Observation of the Strain Field Produced by Coherent Precipitated Particles in an Age-hardened Alloy, Philos Mag 3:531-535.

Pearson, W.B. (1964): A Handbook of Lattice Spacings and Structures of Metals and Alloys, London: Pergamon Press, p. 412.

Prasad, A. ; Eng, T. ; and Mukherjee, K. (1976): Electron Microscopic Studies of Hardening in Type III Dental Alloy, Mater Sci Eng 43:179-185.

Udoh, K. ; Hisatsune, K. ; Yasuda, K. ; and Ohta, M. (1984): Isothermal Age-Hardening Behaviour in Commercial Dental Gold Alloys Containing Palladium, Dent Mater J 3:253-261.

Wise, E.M. ; Crowell, W. ; and Eash, J.T. (1932): The Role of the Platinum Metals in Dental Alloys II, Trans Met Soc AIME 99:363-412.

Wise, E.M. and Eash, J.T. (1933): The Role of the Platinum Metals in Dental Alloys III, Trans Met Soc AIME 104:276-307.

10.

Yasuda, K. and Kanzawa, Y. (1977): Electron Microscope Observation in an Age-hardenable Dental Gold Alloy, Trans Jpn Inst Met 18:46-54.

11.

Yasuda, K. and Ohta, M. (1980): Age-hardening Characteristics of a Commercial Dental Gold Alloy, J Less-Comm Met 70:75-87.

12.

Yasuda, K. ; Udoh, K. ; Hisatsune, K. ; and Ohta, M. (1983): Structural Changes Induced by Ageing in Commercial Dental Gold Alloys Containing Palladium, Dent Mater J 2:48-58.

13.

Yasuda, K. ; Vantendeloo, G. ; Van Landuyt, J. ; and Amelinckx, S. (1986): High-resolution Electron Microscopic Study of Age- hardening in a Commercial Dental Gold Alloy, J Dent Res 65:1179-1185.

Age-hardening Mechanisms in a Commercial Dental Gold Alloy Containing Platinum and Palladium

Abstract

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