Hardening behavior after high-temperature solution treatment of Ag–20Pd–12Au–xCu alloys with different Cu contents for dental prosthetic restorations

Ag–Pd–Au–Cu alloys have been used widely for dental prosthetic applications. Significant enhancement of the mechanical properties of the Ag–20Pd–12Au–14.5Cu alloy as a result of the precipitation of the β′ phase through high-temperature solution treatment (ST), which is different from conventional a...

Full description

Saved in:
Bibliographic Details
Published in:Journal of the mechanical behavior of biomedical materials 2014-07, Vol.35, p.123-131
Main Authors: Kim, Yonghwan, Niinomi, Mitsuo, Hieda, Junko, Nakai, Masaaki, Cho, Ken, Fukui, Hisao
Format: Article
Language:English
Subjects:
Alloys - chemistry
Copper - chemistry
Dental Ag–20Pd–12Au–xCu alloys
Dental Alloys - chemistry
Dental materials
Dental Materials - chemistry
Dental Prosthesis
Dental Stress Analysis - methods
Diffusion
Gold - chemistry
Hardening
Hardness
Heat treatment
Hot Temperature
L10-type ordered β′ phase
Materials Testing
Mechanical properties
Microscopy, Electron, Scanning Transmission
Precipitation
Prosthetics
Silver base alloys
Spectrophotometry
Stress, Mechanical
Tensile Strength
X-Ray Diffraction
X-Rays
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Ag–Pd–Au–Cu alloys have been used widely for dental prosthetic applications. Significant enhancement of the mechanical properties of the Ag–20Pd–12Au–14.5Cu alloy as a result of the precipitation of the β′ phase through high-temperature solution treatment (ST), which is different from conventional aging treatment in these alloys, has been reported. The relationship between the unique hardening behavior and precipitation of the β′ phase in Ag–20Pd–12Au–xCu alloys (x=6.5, 13, 14.5, 17, and 20mass%) subjected to the high-temperature ST at 1123K for 3.6ks was investigated in this study. Unique hardening behavior after the high-temperature ST also occurs in Ag–20Pd–12Au–xCu alloys (x=13, 17, and 20) with precipitation of the β′ phase. However, hardening is not observed and the β′ phase does not precipitate in the Ag–20Pd–12Au–6.5Cu alloy after the same ST. The tensile strength and 0.2% proof stress also increase in Ag–20Pd–12Au–xCu alloys (x=13, 14.5, 17, and 20) after the high-temperature ST. In addition, these values after the high-temperature ST increase with increasing Cu content in Ag–20Pd–12Au–xCu alloys (x=14.5, 17, and 20). The formation process of the β′ phase can be explained in terms of diffusion of Ag and Cu atoms and precipitation of the β′ phase. Clarification of the relationship between hardening and precipitation of the β′ phase via high-temperature ST is expected to help the development of more effective heat treatments for hardening in Ag–20Pd–12Au–xCu alloys. [Display omitted] •β′ phase of Ag–20Pd–12Au–14.5Cu precipitates after high-temp. solution treatment.•Mechanical strength of Ag–20Pd–12Au–14.5Cu is enhanced as a result.•The same enhancement occurs in Ag–20Pd–12Au–xCu alloys (x=13, 17, 20).•Mechanical-strength enhancement and precipitation are absent in Ag–20Pd–12Au–6.5Cu.•Formation of β′ phase can be explained in terms of diffusion and precipitation.
ISSN:1751-6161
1878-0180
DOI:10.1016/j.jmbbm.2014.03.006