Nanomechanics of minerals: understandings and developments through instrumented nanoindentation techniques

Understanding the dynamics of the lithosphere relies heavily on the scale-dependent rheology of minerals. While quartz, feldspar, and phyllosilicates are the key phases to govern the rheology of the crust and tectonic margins, olivine and other mafic phases control the same in the upper mantle. Phas...

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Bibliographic Details
Published in:Physics and chemistry of minerals 2023-03, Vol.50 (1), p.10, Article 10
Main Authors: Mukherjee, Rajiv, Misra, Santanu
Format: Article
Language:English
Subjects:
Crystallography and Scattering Methods
Data acquisition
Deformation
Deformation mechanisms
Earth and Environmental Science
Earth Sciences
Fracture surfaces
Fracture toughness
Geochemistry
Hardness tests
High pressure
High temperature
Lithosphere
Mineral Resources
Mineralogy
Minerals
Modulus of elasticity
Nanoindentation
Olivine
Phase transitions
Polymorphism
Review Article
Rheological properties
Rheology
Single crystals
Size effects
Surface energy
Tectonics
Upper mantle
Yield stress
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Summary:Understanding the dynamics of the lithosphere relies heavily on the scale-dependent rheology of minerals. While quartz, feldspar, and phyllosilicates are the key phases to govern the rheology of the crust and tectonic margins, olivine and other mafic phases control the same in the upper mantle. Phase transition, solid-state substitution, polymorphism, etc. also affect mineral phase rheology. High pressure–temperature deformation tests with natural, synthetic and analog materials have improved our interpretation of the geodynamic state of the lithosphere. However, deforming and studying a single crystal is not easy, because of the scarcity of specimens and laborious sample preparations. Experimental micro- to nanoindentation at room and/or elevated temperatures has proven to be a convenient method over mesoscale compressive testing. Micro- to nanoindentation technique enables higher precision, faster data acquisition and ultra-high resolution (nanoscale) load and displacement. Hardness, elastic moduli, yield stress, fracture toughness, fracture surface energy and rate-dependent creep of mono- or polycrystalline minerals are evaluated using this technique. Here, we present a comprehensive assessment of micro- to nano-mechanics of minerals. We first cover the fundamental theories of instrumented indentation, experimental procedures, pre- and post-indentation interpretations using various existing models followed by a detailed discussion on the application of nanoindentation in understanding the rheology and deformation mechanisms of various minerals commonly occur in the crust and upper mantle. We also address some of the major limitations of indentation tests (e.g., indentation size effect). Finally, we suggest potential future research areas in mineral rheology using instrumented indentation.
ISSN:0342-1791
1432-2021
DOI:10.1007/s00269-023-01235-8