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Thermally Activated Deformation Mechanisms in MgO Investigated via High Temperature Scanning Indentation

Sos, Marcel ; Preuß, Oliver 1; Bruns, Sebastian; Durst, Karsten
1 Institut für Angewandte Materialien (IAM), Karlsruher Institut für Technologie (KIT)

Abstract:

Magnesium oxide (MgO) serves as a model material for plastically deformable ceramics. In previous studies, it has mainly been investigated via uniaxial compression, with studies often focusing on a particular deformation mechanism and temperature range. In this work, the novel high temperature scanning indentation (HTSI) nanoindentation method is applied to characterize the mechanical properties of single-crystalline MgO from room temperature to 800°C, allowing a quasi-continuous measurement of hardness, elastic modulus, the coefficient of strain rate sensitivity, and the activation volume.

Results show that the hardness is controlled by hard 1/2<110>{100} slip, while the activation parameters are influenced by both 1/2<110>{100} and 1/2<110>{110} slip systems. The temperature dependence of the hardness follows two linear regimes, while the strain rate sensitivity shows complex behavior with a maximum of m = 0.05 at a temperature of 675°C. In the same regime, the activation volume remains approximately constant at V = 10–20 b$^3$. At higher temperatures, it increases to V = 100 b$^3$. The combined hardness and activation parameter data enable the determination of transition temperatures between different deformation regimes. ... mehr


Verlagsausgabe §
DOI: 10.5445/IR/1000195220
Veröffentlicht am 13.07.2026
Cover der Publikation
Zugehörige Institution(en) am KIT Institut für Angewandte Materialien (IAM)
Publikationstyp Zeitschriftenaufsatz
Publikationsmonat/-jahr 07.2026
Sprache Englisch
Identifikator ISSN: 0002-7820, 1551-2916
KITopen-ID: 1000195220
Erschienen in Journal of the American Ceramic Society
Verlag American Ceramic Society
Band 109
Heft 7
Seiten e70977
Vorab online veröffentlicht am 01.07.2026
Schlagwörter deformation mechanism, dislocation, high temperature, MgO, nanoindentation
Nachgewiesen in Scopus
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