Metallurgical Structure and Microhardness of Four New Palladium-Based Alloys |
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| Authors: | Stanley G Vermilyea DMD MS Zhuo Cai BDS MS William A Brantley PhD John C Mitchell BS |
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| Institution: | Associate professor and Chair, Section of Primary Care, College of Dentistry, The Ohio State University;Doctoral graduate student. Oral Biology, College of Dentistry, The Ohio State University;Professor, Section of Restorative Dentistry, Prosthodontics and Endodontics, and Director, Graduate Program in Dental Materials, College of Dentisty, The Ohio State University;Senior Electron Microscopist, Department of Geological Sciences, and doctoral graduate student, The Ohio State University |
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| Abstract: | Purpose This investigation compared the Vickers hardness and microstructures of four recently marketed, palladium-based alloys for metal-ceramic restorations. Materials and Methods Wax patterns simulating copings for maxillary central incisors were invested in a fine-grained, carbon-free, phosphate-bonded investment. Following burnout, the palladium alloys were fused with a gas-oxygen torch, centrifugally cast, and bench-cooled. Representative castings were embedded in transparent metallographic resin and sectioned to yield two mirror-image specimens. The specimens were evaluated in either the as-cast condition or following heat treatment simulating the firing cycles for Vita VMK porcelain. Vickers hardness measurements (n = 50) were made using a 1-kg load, and photomicrographs of polished and etched specimens were obtained with a scanning electron microscope. Results The measured values of microhardness for the as-cast alloys were in excellent agreement with values reported by the manufacturer. The hardness in the as-cast condition was significantly greater for the Pd-Cu-Ga-In alloy, compared with the other three alloys, which did not contain copper. For the three high-palladium (≥ 75 wt%) alloys, there were small (4%-8%) decreases in hardness following heat treatment, whereas a larger decrease (13%) in hardness occurred for the Pd-Ag-In-Sn alloy after heat treatment. The porcelain firing cycles caused microstructural homogenization for all four alloys, and the relatively thick near-surface oxidation region in the Pd-Cu-Ga-In and Pd-Ag-In-Sn alloys was not observed in the two heat-treated Pd-Ga-Ag-In-Au alloys. Conclusions The multiphasic microstructures of these alloys may have some significance for the in vitro and clinical corrosion behavior and the metal-ceramic bond strength. The hardness for the three high-palladium alloys may be controlled by submicroscopic precipitates that remain unaltered by heat treatment. The significantly greater hardness for the Pd-Cu-Ga-In alloy may cause greater difficulty for finishing castings in the dental laboratory compared with the other three alloys studied. The strengthening mechanism for the Pd-Ag-In-Sn alloy has significant temperature dependence, which might be exploited to achieve optimum mechanical properties. |
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| Keywords: | casting alloys palladium alloys microstructure mechanical properties hardness |
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