Nanoindentation of Al2O3/Al2TiO5 composites: Small-scale mechanical properties of Al2TiO5 as reinforcement phase

The mechanical properties of alumina/aluminum titanate composites (Al2O3/Al2TiO5) were evaluated and analyzed by nanoindentation. Indentations with different penetration depths were performed, and residual imprints on specimens were located and observed by combining complementary characterization te...

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Veröffentlicht in:	Journal of the European Ceramic Society 2012-11, Vol.32 (14), p.3723-3731
Hauptverfasser:	Botero, C.A., Jiménez-Piqué, E., Baudín, C., Salán, N., Llanes, L.
Format:	Artikel
Sprache:	eng
Schlagworte:	Al2O3 Al2TiO5 Aluminum oxide Aluminum titanates Composites Crack initiation Elastic modulus Indentation Mechanical properties Nanoindentation Penetration depth
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container_title	Journal of the European Ceramic Society
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creator	Botero, C.A. Jiménez-Piqué, E. Baudín, C. Salán, N. Llanes, L.
description	The mechanical properties of alumina/aluminum titanate composites (Al2O3/Al2TiO5) were evaluated and analyzed by nanoindentation. Indentations with different penetration depths were performed, and residual imprints on specimens were located and observed by combining complementary characterization techniques. The mechanical response of composites was found to be determined by grain size of alumina and aluminum titanate, as evaluated from indentations performed at 1500nm of penetration depth. On the other hand, small indents in individual grains permitted to assess the hardness as well as the elastic modulus of non-cracked particles of Al2TiO5 through implementation of different analytical indentation models. The attained values for the local mechanical properties were validated through critical comparison of them with those predicted by the rule of mixtures. Results showed no evidence of microcracking on grains of the reinforcing phase for all the tested composites, before and after low penetration depth indentations. Elastic modulus of Al2TiO5 was found to be higher than the values reported on bulk aluminum titanate, presumably because of the absence of microcracking for small grain sizes. The bulk composite mechanical response is finally discussed on the basis of contributions from those of the individual phases.
doi_str_mv	10.1016/j.jeurceramsoc.2012.05.034
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Indentations with different penetration depths were performed, and residual imprints on specimens were located and observed by combining complementary characterization techniques. The mechanical response of composites was found to be determined by grain size of alumina and aluminum titanate, as evaluated from indentations performed at 1500nm of penetration depth. On the other hand, small indents in individual grains permitted to assess the hardness as well as the elastic modulus of non-cracked particles of Al2TiO5 through implementation of different analytical indentation models. The attained values for the local mechanical properties were validated through critical comparison of them with those predicted by the rule of mixtures. Results showed no evidence of microcracking on grains of the reinforcing phase for all the tested composites, before and after low penetration depth indentations. Elastic modulus of Al2TiO5 was found to be higher than the values reported on bulk aluminum titanate, presumably because of the absence of microcracking for small grain sizes. 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Indentations with different penetration depths were performed, and residual imprints on specimens were located and observed by combining complementary characterization techniques. The mechanical response of composites was found to be determined by grain size of alumina and aluminum titanate, as evaluated from indentations performed at 1500nm of penetration depth. On the other hand, small indents in individual grains permitted to assess the hardness as well as the elastic modulus of non-cracked particles of Al2TiO5 through implementation of different analytical indentation models. The attained values for the local mechanical properties were validated through critical comparison of them with those predicted by the rule of mixtures. Results showed no evidence of microcracking on grains of the reinforcing phase for all the tested composites, before and after low penetration depth indentations. Elastic modulus of Al2TiO5 was found to be higher than the values reported on bulk aluminum titanate, presumably because of the absence of microcracking for small grain sizes. The bulk composite mechanical response is finally discussed on the basis of contributions from those of the individual phases.</abstract><pub>Elsevier Ltd</pub><doi>10.1016/j.jeurceramsoc.2012.05.034</doi><tpages>9</tpages></addata></record>
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subjects	Al2O3 Al2TiO5 Aluminum oxide Aluminum titanates Composites Crack initiation Elastic modulus Indentation Mechanical properties Nanoindentation Penetration depth
title	Nanoindentation of Al2O3/Al2TiO5 composites: Small-scale mechanical properties of Al2TiO5 as reinforcement phase
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