期刊
JOURNAL OF THE AMERICAN CERAMIC SOCIETY
卷 104, 期 1, 页码 5-22出版社
WILEY
DOI: 10.1111/jace.17502
关键词
deformation; fatigue; fracture; indentation; machining; micromechanics; microstructure; wear
资金
- Junta de Extremadura, Spain, FEDER/ERDF [IB16139, GR18149]
- Ministry of Science and Innovation, spain [PID2019105377RB-I00]
- Australian Research Council (ARC) [DP180103275]
- US National Institute of Dental and Craniofacial Research [R01DE017925, R01DE026279, R01DE026772]
- US National Science Foundation [CMMI-0758530]
Hard and brittle solids with covalent/ionic bonding are widely used in modern manufacturing technologies, and optimizing shaping processes can reduce manufacturing time and cost while extending component longevity. However, the same processes can also contribute to wear and fatigue degradation in service. Education development of advanced finishing protocols for this class of solids requires a comprehensive understanding of damage mechanisms at small-scale contacts from a materials perspective. The role of microstructure in material removal modes is highlighted, and pathways to future research—experimental, analytical, and computational—are indicated.
Hard and brittle solids with covalent/ionic bonding are used in a wide range of modern-day manufacturing technologies. Optimization of a shaping process can shorten manufacturing time and cost of component production, and at the same time extend component longevity. The same process can contribute to wear and fatigue degradation in service. Educated development of advanced finishing protocols for this class of solids requires a comprehensive understanding of damage mechanisms at small-scale contacts from a materials perspective. The basic science of attendant deformation and removal modes in contact events is here analyzed and discussed in the context of brittle and ductile machining and severe and mild wear. Essentials of brittle-ductile transitions in micro- and nano-indentation fields are outlined, with distinctions between blunt and sharp contacts and axial and sliding loading. The central role of microstructure in material removal modes is highlighted. Pathways to future research-experimental, analytical, and computational-are indicated.
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