Ceramics and Composite Materials

Biography

Biography: Yan Huang

Abstract

Mg and its alloy have shown great potential for orthopaedic and cardiovascular applications due to their excellent biocompatibility and biodegradability. However, they corrode too quickly in vivo, which limits their clinical use. Hydroxyapatite (HA) is a natural bone component and the addition of HA into Mg alloys has been demonstrated to enhance corrosion resistance. In the present work, Mg/HA nanocomposites were designed based on a new concept of corrosion protection mechanism and fabricated by a novel casting-deformation route, which combined high shear solidification and severe plastic deformation. High purity Mg-2Zn-0.1Mn-0.5Ca (wt%) was used as the matrix alloy and HA nanoparticles of 30-50 nm in diameter were added into the matrix melt by using a rotor stator mixer, which rotated at 5,000-20,000 rpm during mixing. Cylindrical composite ingots (60×100 mm) were cast in a steel mould at a mixing and pouring temperature of ~670ï‚°C. The as-cast composite ingots were then extruded at 350ï‚°C into a square bar with a cross-section of 15×15 mm, which were further deformed by equal channel angular extrusion (ECAE). Optical and electron microscopy was carried out to characterize the microstructure of the fabricated Mg/HA nanocomposites. Mechanical properties were tested by uniaxial compression tests at room temperature. Polarization and immersion tests were conducted in the Hank solution at 37ï‚°C, according to ASTM-G31-T2, to study the in vitro corrosion behaviour of the material. The fabricated Mg/HA nanocomposites exhibited a fine grain structure and uniform global HA particle distribution with largely enhanced both mechanical properties and corrosion resistance.