Age-hardenability and related microstructural changes during and after phase transformation in an Au-Ag-Cu-based dental alloy

Abstract: The aim of this study was to clarify how the microstructural changes during and after phase transformation determine the age-hardenability of an Au-Ag-Cu-based dental alloy. The rapid increase in hardness in the initial stage was the result of rapid atomic diffusion by spinodal decomposition into metastable Ag-rich' and Cu-rich' phases. The constant hardening after apparent initial hardening was the result of a subsequent transformation of the metastable Ag-rich' and Cu-rich' phases to the stable Ag-rich α 1 p… Show more

“…2a) shows the same and even more pronounced shoulders on the fundamental L10 peaks. These shoulders most likely correspond to the α2 phase, which is an FCC phase with Au and Ag in solid solution [3,17,18,30].…”

“…At later stages, coarse twin lamellae are formed to accommodate the long-range strains arising from the growth of ordered regions with different c-axis orientations. The dental compatibility of the ternary Au-Cu-Ag system has steered the efforts into understanding the order-hardening mechanism [13] and age-hardening characteristics [13][14][15][15][16][17][18][19][20][21] of these alloys. The addition of small silver amounts to the binary equiatomic AuCu extends the early stages of ordering to longer ageing times by reducing the ordering rate [22], delaying the growth of inter-twin spacing as well as slowing down the growth of anti-phase domains [3].…”

Influence of thermo-mechanical history on the ordering kinetics in 18 carat Au alloys

“…2a) shows the same and even more pronounced shoulders on the fundamental L10 peaks. These shoulders most likely correspond to the α2 phase, which is an FCC phase with Au and Ag in solid solution [3,17,18,30].…”

“…At later stages, coarse twin lamellae are formed to accommodate the long-range strains arising from the growth of ordered regions with different c-axis orientations. The dental compatibility of the ternary Au-Cu-Ag system has steered the efforts into understanding the order-hardening mechanism [13] and age-hardening characteristics [13][14][15][15][16][17][18][19][20][21] of these alloys. The addition of small silver amounts to the binary equiatomic AuCu extends the early stages of ordering to longer ageing times by reducing the ordering rate [22], delaying the growth of inter-twin spacing as well as slowing down the growth of anti-phase domains [3].…”

Influence of thermo-mechanical history on the ordering kinetics in 18 carat Au alloys

“…With the rapid development of the aerospace, shipping and other industries, the requirements for the electrical contacting property, chemical performance, mechanical performance, and other aspects of conductive rings are continuously increasing. The demand for long-life conductive rings with a high strength, wear resistance, and corrosion resistance has increased significantly [1][2][3]. Among the array of precious metal electrical contact materials, gold stands out for its unrivaled chemical stability, commendable electrical conductivity, low elastic modulus, and remarkable wear resistance.…”

“…These alloys exhibit superior elasticity, robust wear resistance, corrosion resistance, and low contact resistance. They find applications as elastic brush materials in precision potentiometers and as contact materials in miniature relays [3,5].…”

Effect of Cold Deformation and Heat Treatment on the Microstructures and Mechanical Properties of Au-15Ag-12Cu-6Ni Alloy Sheets

The effects of discontinuous precipitation and ordering on the age-hardening in Au-20Ag-30Cu (wt.%) alloy