2007
DOI: 10.1098/rspa.2007.1829
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On a ferroelastic mechanism governing the toughness of metastable tetragonal-prime ( t ′) yttria-stabilized zirconia

Abstract: This article investigates the toughness of yttria-stabilized zirconia (YSZ) with the tetragonal-prime ( t ′) structure. Such materials are used as durable thermal barriers in gas turbines. Their durability has been attributed to high toughness, relative to materials in the cubic phase field. Based on prior literature, a ferroelastic toughening mechanism is hypothesized and this assertion is examined by characterizing the material in the wake of an indentation-induced crack. Assessment b… Show more

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Cited by 231 publications
(173 citation statements)
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“…Similar mechanisms may also be active in other materials, given that soft vibrational modes and tetragonal-cubic phase transitions are not a unique feature of zirconia. Even more importantly, the discussed dynamics supports the models that ascribe the durability of TBCs to a remarkable toughening mechanism based on ferroelastic switching: The reorientation of tetragonal domains under the stress field of a crack yields a residual stress field that shields the crack tip and increases the work of fracture [2,3]. Our calculations show that doping with YO 1.5 stabilizes the tetragonal structure, but also lifts the degeneracy between the various tetragonal orientations, so that ferroelastic switches may become a viable mechanism to absorb energy during crack propagation.…”
mentioning
confidence: 63%
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“…Similar mechanisms may also be active in other materials, given that soft vibrational modes and tetragonal-cubic phase transitions are not a unique feature of zirconia. Even more importantly, the discussed dynamics supports the models that ascribe the durability of TBCs to a remarkable toughening mechanism based on ferroelastic switching: The reorientation of tetragonal domains under the stress field of a crack yields a residual stress field that shields the crack tip and increases the work of fracture [2,3]. Our calculations show that doping with YO 1.5 stabilizes the tetragonal structure, but also lifts the degeneracy between the various tetragonal orientations, so that ferroelastic switches may become a viable mechanism to absorb energy during crack propagation.…”
mentioning
confidence: 63%
“…Indeed, excess doping eventually leads to stabilization of the cubic form with a much lower toughness [2]. In contrast thereto, recent work involving doping with Y 3+ and Ti 4+ has led to tetragonal alloys with superior phase stability and improved toughness [3].…”
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confidence: 96%
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“…Ferroelastic toughening of metastable 7YSZ coatings has been demonstrated and is believed to be responsible for the unusual toughness of the 7YSZ coatings. [31] The attainable ferroelastic toughening is proportional to both the tetragonality and the coercive stress [31] so while the tetragonality decreases with increasing zirconia content it remains to be determined how the coercive stress varies and hence the attainable toughness.…”
Section: Discussionmentioning
confidence: 99%