2018
DOI: 10.1021/acsami.8b02338
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Ultrafine Ceramic Grains Embedded in Metallic Glass Matrix: Achieving Superior Wear Resistance via Increase in Both Hardness and Toughness

Abstract: As structural materials, crystalline or metallic glass materials have attracted scientific and practical interests. However, some mechanisms involving critical size and shear bands have adverse effects on their mechanical properties. Here, we counter these two effects by introducing a special structure with ultrafine ceramic grains (with a diameter of ∼2.0 nm) embedded into a metallic glass matrix, wherein the grains are mainly composed of a Ta-W-N solid solution structure in nature, surrounded by a W-based am… Show more

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Cited by 28 publications
(12 citation statements)
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“…It forms very tightly intertwined and integrated networks, giving rise to a uniformly distributed dual-phase structure. The softer phase in such a composite structure is known to restrain the movement of dislocations in the grains of the stronger phase, thus improving the overall toughness via structural relaxation that promotes intrinsic crack self-consumption. , The resulting dense DPNC film has a very smooth surface that is highly conducive to reducing friction and wear; meanwhile, the finely intertwined dual-phase nanostructure effectively protects MoS 2 by limiting its exposure to environmental pollutants. Moreover, the tightly compacted nanostructure is optimally designed to regulate the orderly consumption and offer a long-lasting continuous supply of the lubricant via a friction-driven mechanism.…”
Section: Resultsmentioning
confidence: 99%
“…It forms very tightly intertwined and integrated networks, giving rise to a uniformly distributed dual-phase structure. The softer phase in such a composite structure is known to restrain the movement of dislocations in the grains of the stronger phase, thus improving the overall toughness via structural relaxation that promotes intrinsic crack self-consumption. , The resulting dense DPNC film has a very smooth surface that is highly conducive to reducing friction and wear; meanwhile, the finely intertwined dual-phase nanostructure effectively protects MoS 2 by limiting its exposure to environmental pollutants. Moreover, the tightly compacted nanostructure is optimally designed to regulate the orderly consumption and offer a long-lasting continuous supply of the lubricant via a friction-driven mechanism.…”
Section: Resultsmentioning
confidence: 99%
“…In addition to high H/E, large recoverable strain is also reported as an important contributor to the improved tribological performance [16,28,45]. This is because that large recoverable strain is able to make the deformation spring back into its original state as much as possible when removing external stress.…”
Section: Mechanical Propertiesmentioning
confidence: 99%
“…Although the average COF and wear resistance of the partially crystallized film are not the best compared with the result in open literature [69], this work concludes an effective and simple method for increasing the hardness and especially H/E, i.e., embedding the crystalline phase into its amorphous counterpart to reduce the elastic modulus by Voigt model while increase the hardness by composite effect. In addition, introducing the second phase, such as nitride phase, that has higher hardness and elastic modulus than the matrix phase can also increase the hardness and H/E [16]. This is because that, although such the second phase can increase both hardness and elastic modulus, the increase in hardness is more significant than the increase in elastic modulus.…”
Section: Friction and Wear Reduction Mechanismmentioning
confidence: 99%
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“…Furthermore, on the worn surface, The H/E were all increased and the values in nanocarbon reinforced composites were still higher than that of pure HA. According to Hooke's law, by reducing elasticity modulus, the material is able to sustain higher elastic deformation prior to a failure at a given load [181].…”
mentioning
confidence: 99%