Metal-ceramic joints represent an important choice for biomedical devices, in orthopaedic field or as micro-stimulators. ZrO2-Ag-HEA joint is here proposed to replace the currently used Ti6Al4V by new Ti-based refractory HEAs. To evaluate the system reactivity, wettability of ZrO2 by different Ag-based alloys at 1000 degrees C and their interfacial layers were studied, for the first time. Interpretation and discussion of systems reactivity were supported by thermodynamic calculations, according to the CALPHAD approach and the ad-hoc Ag-Ti-Zr-O thermodynamic database, implemented in this work. A good wettability was reached at 1000 degrees C adding Ti to Ag: Ag-4Ti and Ag-8Ti reached contact angles of 81-85 degrees. Ag-4Ti-2Zr showed the best wettability (77 degrees) and the most complex interfacial microstructure. A continuous hcp (Ti,O), similar to 20 mu m thick, promoted the wettability of Ag-4Ti and Ag-8Ti. In both cases, AgTi was the only intermetallic compound found in the bulk. Ag-4Ti-2Zr formed a thicker interfacial layer of hcp-(Ti,Zr,O) + bcc-(Ti,Zr) + a less compact Ag(Ti,Zr)(2) layer. Here, a low amount of Ag(Ti,Zr) and Ag(Ti,Zr)(2) was found in the Ag matrix. Since Ag resulted a promising filler to braze Ti-rich substrates to ZrO2 at 1000 degrees C, preliminary HEA-Ag-ZrO2 joints were characterized. A sound and defects-free interface was observed, with a first layer, mainly formed by Ag, Ti and Zr (HV similar to 600), and a Ag-based interface (HV similar to 250), extending until the HEA. Further works envisage mechanical and electrochemical evaluations of the system to pave the way for the production of novel HEA-Ag-ZrO2 joints to be used in biomedical applications. (C) 2022 Published by Elsevier B.V.

Zirconia-High Entropy Alloys joints for biomedical applications: the role of Ag-based fillers on interfacial reactivity

S. Gambaro;P. Riani;G. Cacciamani
2022-01-01

Abstract

Metal-ceramic joints represent an important choice for biomedical devices, in orthopaedic field or as micro-stimulators. ZrO2-Ag-HEA joint is here proposed to replace the currently used Ti6Al4V by new Ti-based refractory HEAs. To evaluate the system reactivity, wettability of ZrO2 by different Ag-based alloys at 1000 degrees C and their interfacial layers were studied, for the first time. Interpretation and discussion of systems reactivity were supported by thermodynamic calculations, according to the CALPHAD approach and the ad-hoc Ag-Ti-Zr-O thermodynamic database, implemented in this work. A good wettability was reached at 1000 degrees C adding Ti to Ag: Ag-4Ti and Ag-8Ti reached contact angles of 81-85 degrees. Ag-4Ti-2Zr showed the best wettability (77 degrees) and the most complex interfacial microstructure. A continuous hcp (Ti,O), similar to 20 mu m thick, promoted the wettability of Ag-4Ti and Ag-8Ti. In both cases, AgTi was the only intermetallic compound found in the bulk. Ag-4Ti-2Zr formed a thicker interfacial layer of hcp-(Ti,Zr,O) + bcc-(Ti,Zr) + a less compact Ag(Ti,Zr)(2) layer. Here, a low amount of Ag(Ti,Zr) and Ag(Ti,Zr)(2) was found in the Ag matrix. Since Ag resulted a promising filler to braze Ti-rich substrates to ZrO2 at 1000 degrees C, preliminary HEA-Ag-ZrO2 joints were characterized. A sound and defects-free interface was observed, with a first layer, mainly formed by Ag, Ti and Zr (HV similar to 600), and a Ag-based interface (HV similar to 250), extending until the HEA. Further works envisage mechanical and electrochemical evaluations of the system to pave the way for the production of novel HEA-Ag-ZrO2 joints to be used in biomedical applications. (C) 2022 Published by Elsevier B.V.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11567/1108653
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