Single-crystal alumina under nanoindentation: loading rate effect Article Swipe
Manjima Bhattacharya
,
Arjun Dey
,
Anoop K. Mukhopadhyay
·
YOU?
·
· 2017
· Open Access
·
· DOI: https://doi.org/10.1107/s2053273317086193
YOU?
·
· 2017
· Open Access
·
· DOI: https://doi.org/10.1107/s2053273317086193
Sapphire is a single crystal form of alumina in the purest form with no porosity or grain boundaries, making it theoretically dense.There is an increasing demand in airborne applications and UAVs for large sapphire windows capable of hosting various equipment sets, working at different wavelengths under its coverage that combines high optical transmission, low transmitted wavefront distortion and outstanding mechanical strength properties at high and low temperatures.However, they are vulnerable to nanoscale contact induced static and dynamic damages.The present work therefore reports the nanomechanical properties of a single crystal alumina or sapphire as a function of variations in loading rates e.g., 10-10000 microN.s-1.The nanohardness (H) of sapphire shows significant enhancement of ~ 66% from about 20 to 34 GPa with the variation in loading rates.The load-depth plots reveal the presence of multiple micro-pop-in and micro-pop-out events which signify the occurrences of nanoscale plasticity events in the sapphire under nanoindentation.The critical load (Pc) i.e., the load at which nanoscale plasticity events initiate increases with the loading rates.This result implies an inherent capability of sapphire to increase its intrinsic contact deformation resistance the more quickly we try to deform it.These results are explained in terms of the maximum shear stress (τmax) generated underneath the nanoindenter.
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- Type
- article
- Language
- en
- Landing Page
- https://doi.org/10.1107/s2053273317086193
- http://journals.iucr.org/a/issues/2017/a2/00/a56051/a56051.pdf
- OA Status
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- OpenAlex ID
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- DOI
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https://doi.org/10.1107/s2053273317086193Digital Object Identifier
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Single-crystal alumina under nanoindentation: loading rate effectWork title
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articleOpenAlex work type
- Language
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enPrimary language
- Publication year
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2017Year of publication
- Publication date
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2017-12-01Full publication date if available
- Authors
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Manjima Bhattacharya, Arjun Dey, Anoop K. MukhopadhyayList of authors in order
- Landing page
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https://doi.org/10.1107/s2053273317086193Publisher landing page
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https://journals.iucr.org/a/issues/2017/a2/00/a56051/a56051.pdfDirect link to full text PDF
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YesWhether a free full text is available
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bronzeOpen access status per OpenAlex
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https://journals.iucr.org/a/issues/2017/a2/00/a56051/a56051.pdfDirect OA link when available
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Nanoindentation, Materials science, Composite material, Crystal (programming language), Metallurgy, Crystallography, Chemistry, Computer science, Programming languageTop concepts (fields/topics) attached by OpenAlex
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0Total citation count in OpenAlex
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10Other works algorithmically related by OpenAlex
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| abstract_inverted_index.significant | 108 |
| abstract_inverted_index.transmitted | 54 |
| abstract_inverted_index.wavelengths | 44 |
| abstract_inverted_index.applications | 28 |
| abstract_inverted_index.micro-pop-in | 132 |
| abstract_inverted_index.nanohardness | 103 |
| abstract_inverted_index.micro-pop-out | 134 |
| abstract_inverted_index.nanoindenter. | 202 |
| abstract_inverted_index.theoretically | 20 |
| abstract_inverted_index.transmission, | 52 |
| abstract_inverted_index.microN.s-1.The | 102 |
| abstract_inverted_index.nanomechanical | 83 |
| abstract_inverted_index.nanoindentation.The | 148 |
| abstract_inverted_index.temperatures.However, | 66 |
| cited_by_percentile_year | |
| corresponding_author_ids | https://openalex.org/A5019578313 |
| countries_distinct_count | 1 |
| institutions_distinct_count | 3 |
| corresponding_institution_ids | https://openalex.org/I127439422 |
| citation_normalized_percentile.value | 0.20281455 |
| citation_normalized_percentile.is_in_top_1_percent | False |
| citation_normalized_percentile.is_in_top_10_percent | False |