Design of Fe-based Bulk Metallic Glasses with Improved Wear Resistance
Yi-Cheng Li, Cheng Zhang, Wei Xing, Sheng-Feng Guo, and Lin Liu
Abstract
The application of bulk metallic glasses (BMGs) as advanced wear-resistant materials has remained limited despite optimistic expectations. In this work, we develop a series of novel Fe-based BMGs with improved wear resistance by altering the Cr and Mo contents in an Fe-Cr-Mo-C-B-Y glass forming system. Experimental results demonstrate that increasing Cr and Mo contents enhance the thermal stability and hardness (Hv) of the resulting BMGs without reducing their fracture toughness (Kc). The enhanced hardness is mainly attributed to the increased fraction of the stiff (Cr, Mo)-C covalent bonds in the resultant BMGs, as revealed by X-ray photoelectron spectrograph measurement. Worn surface/subsurface observations and stress field modeling reveal the activity of two kinds of wear mechanisms, i.e., hardness-controlled abrasion wear and toughness-controlled fatigue wear. We further clarify the enhanced wear performance of the Fe-based BMGs according to an effective indicator Kc3/4Hv1/2 that correlates positively with the wear resistance of the samples. The optimal Fe-based BMG sample possessed versatile properties, including a strong glass-forming ability (i.e., a minimum critical diameter of 8 mm), a high hardness of 1335 Hv, and a very low specific wear rate of ~1.3×10-6 mm3 N-1m-1, which represents one of the most outstanding Fe-based BMGs reported thus far.
https://pubs.acs.org/doi/abs/10.1021/acsami.8b11561
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