Realizing reversible phase transformation of shape memory ceramics constrained in aluminum
Small-scale shape memory ceramics exhibit superior shape memory or superelasticity properties, while their integration into a matrix material and the subsequent attainment of their reversible tetragonal-monoclinic phase transformations remains a challenge. Here, cerium-doped zirconia (CZ) reinforced...
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Veröffentlicht in: | Nature communications 2023-11, Vol.14 (1), p.7103-7103, Article 7103 |
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Sprache: | eng |
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Zusammenfassung: | Small-scale shape memory ceramics exhibit superior shape memory or superelasticity properties, while their integration into a matrix material and the subsequent attainment of their reversible tetragonal-monoclinic phase transformations remains a challenge. Here, cerium-doped zirconia (CZ) reinforced aluminum (Al) matrix composite is fabricated, and both macroscopic and microscopic mechanical tests reveal more than doubled compressive strength and energy absorbance of the composites as compared with pure Al. Full austenitization in the CZ single-crystal clusters is achieved when they are constrained by the Al matrix, and reversible martensitic transformation triggered by thermal or stress stimuli is observed in the composite micro-pillars without causing fracture in the composite. These results are interpreted by the strong geometric confinement offered by the Al matrix, the robust CZ/Al interface and the local three-dimensional particle network/force-chain configuration that effectively transfer mechanical loads, and the decent flowability of the matrix that accommodates the volume change during phase transformation.
Achieving reversible phase transformation of shape memory ceramics (SMCs) in a densified composite can have scientific and technological impacts, but is challenging. Here, the authors demonstrate the reversible martensitic transformation of SMCs confined in aluminum without destructive impact. |
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ISSN: | 2041-1723 2041-1723 |
DOI: | 10.1038/s41467-023-42815-0 |