화학공학소재연구정보센터
Materials Chemistry and Physics, Vol.125, No.3, 576-586, 2011
Enhancement of mechanical and tribological properties in AISI D3 steel substrates by using a non-isostructural CrN/AlN multilayer coating
Enhancement of mechanical and tribological properties on AISI D3 steel surfaces coated with CrN/AlN multilayer systems deposited in various bilayer periods (Lambda) via magnetron sputtering has been studied in this work exhaustively. The coatings were characterized in terms of structural, chemical, morphological, mechanical and tribological properties by X-ray diffraction (XRD), electron dispersive spectrograph, atomic force microscopy, scanning and transmission electron microscopy, nanoindentation, pin-on-disc and scratch tests. The failure mode mechanisms were observed via optical microscopy. Results from Xray diffraction analysis revealed that the crystal structure of CrN/AlN multilayer coatings has a NaCl-type lattice structure and hexagonal structure (wurtzite-type) for CrN and AlN, respectively, i.e., made was non-isostructural multilayers. An enhancement of both hardness and elastic modulus up to 28 GPa and 280 GPa, respectively, was observed as the bilayer periods (Lambda) in the coatings were decreased. The sample with a bilayer period (Lambda) of 60 nm and bilayer number n = 50 showed the lowest friction coefficient (similar to 0.18) and the highest critical load (43 N), corresponding to 2.2 and 1.6 times better than those values for the coating deposited with n=1, respectively. The best behavior was obtained when the bilayer period (Lambda) is 60 nm (n=50), giving the highest hardness 28 GPa and elastic modulus of 280 GPa, the lowest friction coefficient (similar to 0.18) and the highest critical load of 43 N. These results indicate an enhancement of mechanical, tribological and adhesion properties, comparing to the CrN/AlN multilayer systems with 1 bilayer at 28%, 21%, 40%, and 30%, respectively. This enhancement in hardness and toughness for multilayer coatings could be attributed to the different mechanisms for layer formation with nanometric thickness such as the Hall-Petch effect and the number of interfaces that act as obstacles for the crack deflection and dissipation of crack energy. (C) 2010 Elsevier B.V. All rights reserved.