A. Gil-Santos scite author profile

In this work the microstructure and degradation behavior of several as-cast alloy compositions belonging to the Mg rich corner of the Mg-Si-Sr system are presented and related. The intermetallic phases are identified and analyzed describing the microstructure evolution during solidification. It is intended in this work to obtain insight in the behavior of the ternary alloys in in vitro tests and to analyze the degradation behavior of the alloys under physiologically relevant conditions. The as-cast specimens have been exposed to immersion tests, both mass loss (ML) and potentiodynamic polarization (PDP). The degradation rate (DR) have been assessed and correlated to microstructure features, impurity levels and alloy composition. The initial reactions resulted to be more severe while the degradation stabilizes with time. A higher DR is related with a high content of the MgSr phase and with the presence of coarse particles of the intermetallics MgSi, MgSiSr and MgSiSr. Specimens with a higher DR typically have higher levels of impurities and alloy contents.

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Eigenstrain simulation of residual stresses induced by laser shock processing in a Ti6Al4V hip replacement

Correa

Gil-Santos

Porro

et al. 2015

Materials & Design

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Laser Shock Processing: an emerging technique for the enhancement of surface properties and fatigue life of high-strength metal alloys

Ocaña

Porro

Morales

et al. 2013

IJMMP

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Microstructure and mechanical characterization of cast Mg-Ca-Si alloys

Gil-Santos

Szakács

Moelans

et al. 2017

Journal of Alloys and Compounds

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Three different phase fields are predicted and experimentally detected in the Mg rich corner of the Mg-Ca-Si ternary diagram. The present phases are Mg + MgCaSi + Mg2Si in phase field 1, Mg + MgCaSi in phase field 2 and Mg + Mg2Ca + MgCaSi in phase field 3. The focus of this study is on the formation and evolution of the intermetallic phases. The final microstructures have been related with their solidification process and with the alloys mechanical properties. A clear influence of the observed intermetallic phases on the mechanical performance was found. A bigger size and higher amounts of the MgCaSi intermetallic phase increase the alloys strength and make them brittle, while in its fine morphology MgCaSi reduces the strengthening effect and slightly decreases the ductility compared to pure Mg. Mg2Si phase in its needle-like small size morphology contributes to an increase of the hardness and compressive strength. Its presence reduces the alloys ductility making them brittle. Finally, the highest values for compressive strength and hardness are related to the Mg2Ca presence.

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A. Gil-Santos

Effect of advancing direction on fatigue life of 316L stainless steel specimens treated by double-sided laser shock peening

Microstructure and degradation performance of biodegradable Mg-Si-Sr implant alloys

Eigenstrain simulation of residual stresses induced by laser shock processing in a Ti6Al4V hip replacement

Laser Shock Processing: an emerging technique for the enhancement of surface properties and fatigue life of high-strength metal alloys

Microstructure and mechanical characterization of cast Mg-Ca-Si alloys

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