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Microstructures and fiber-formation mechanisms of crocidolite asbestos
Jung Ho Ahn
, P R Buseck
Molecular Sciences, School of (SMS)
Earth and Space Exploration, School of (SESE)
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Article
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peer-review
23
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Keyphrases
Formation Mechanism
100%
Microstructure Formation
100%
Planar Defects
100%
Fiber Formation
100%
Crocidolite
100%
Crocidolite Asbestos
100%
Subgrain
50%
Pyriboles
50%
Subgrain Boundary
50%
Fibrous Crystals
50%
Mica
25%
Crystallization
25%
Further Development
25%
Dislocation
25%
Burgers Vector
25%
Tensile Strength
25%
High-resolution Transmission Electron Microscopy (HRTEM)
25%
Crack Propagation
25%
Western Australia
25%
Serpentine
25%
Edge Dislocation
25%
Chlorite
25%
Defect-rich
25%
Chain Structure
25%
Sheet Silicates
25%
Na-rich
25%
Iron Formation
25%
Asbestiform
25%
Hamersley Basin
25%
Crystal Misorientation
25%
Tectonic Stress
25%
Mamba
25%
Riebeckite
25%
Material Science
High-Resolution Transmission Electron Microscopy
100%
Ultimate Tensile Strength
100%
Silicate
100%
Burger Vector
100%
Edge Dislocation
100%
Biochemistry, Genetics and Molecular Biology
High-Resolution Transmission Electron Microscopy
100%
Tensile Strength
100%
Riebeckite
100%
Earth and Planetary Sciences
Riebeckite
100%