Anelastic Effects of Phase Decomposition in 14-Carat AuAgCu Alloy

Iva Tkalcec-Vaju; Daniele Mari; Robert Schaller

doi:10.4028/www.scientific.net/SSP.184.277

Paper Titles

Isothermal Mechanical Spectroscopy in Equiatomic CuZr Alloy
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Micro- and Macro-Plastic Properties of Be Polycrystals
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High Temperature Mechanical Spectroscopy Study of 3 mol% Yttria Stabilized Tetragonal Zirconia Reinforced with Carbon Nanotubes
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High Temperature Internal Friction in Fine Grain and Nano-Crystalline Zirconia
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Anelastic Effects of Phase Decomposition in 14-Carat AuAgCu Alloy
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Grain Boundary Relaxation in 18-Carat Yellow Gold
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The Effect of Annealing on the Internal Friction in ECAP-Modified Ultrafine Grained Copper
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Mechanical Spectroscopy of Annealing Effects in Electrodeposited Nickel/Ceramic Nanocomposites
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Simulation of Mechanical Response in Nanoparticles
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Anelastic Effects of Phase Decomposition in 14-Carat AuAgCu Alloy

Abstract:

A relaxation peak has been observed in the internal friction spectrum of 18-carat AuAgCu yellow gold alloys at about 750K for 0.5Hz. It is related to the presence of grain boundaries, since it is absent in the spectrum of single crystals. For the 14-carat yellow gold alloy (Au38%Ag32%Cu30%), a phase decomposition between silver-rich and copper-rich solid solution occurs in the same temperature range. The effects of the phase decomposition on the internal friction and the dynamic modulus are studied by isochronal and isothermal measurements and correlated with the microstructure evolution. Upon cooling, the phase decomposition starts at grain boundaries at about 840K, producing a fine lamellar structure, and the grain boundary peak amplitude strongly decreases. As the phase decomposition progresses at the interior of the grains upon further cooling, the internal friction background increases. It remains very high in heating until solid solution homogenisation, which occurs above 890K. Such an increase of the internal friction background is observed also in the single crystalline alloy and may be attributed to the interfaces between lamellae of the silver and copper-rich phase.