Correlation between the Microstructure, Growth Mechanism, and Growth Kinetics of Alumina Scales on a FeCrAlY Alloy

Naumenko, D.; Gleeson, Brian; Wessel, E.; Singheiser, L.; Quadakkers, W. J.

doi:10.1007/s11661-007-9342-z

Cited by 115 publications

(70 citation statements)

References 34 publications

(78 reference statements)

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“…The complex morphology of porous surface exposed to the attack and their partial blocking by the oxidation products justifies the logarithmic (or asymptotic) kinetics. Aluminium particles have much surface to be oxidized, and it is reduced significantly during exposure time, so logarithmic adjustments fits better than typical parabolic or sub parabolic kinetics observed for rolled samples [20].…”

Section: Resultsmentioning

confidence: 86%

Oxidation of Micro-Sized Aluminium Particles: Hollow Alumina Spheres

et al. 2013

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Oxidized aluminium microparticles have recently been proposed for manufacturing new, environmentally-friendly, protective coatings on stainlesssteels and Ni-base alloys. The oxidation mechanisms of spherical aluminium microparticles of an average particle size of 3.5 lm were studied. Accordingly, simultaneous differential thermal analysis-thermogravimetry tests were carried out in air at different temperatures, always above aluminium melting temperature. Scanning electron microscopy and XRD were also used for the interpretation of results. Weight gain and energy results were explained in terms of the different structural changes taking place in aluminium particles. Dehydroxylation process was identified. The transformation of amorphous alumina to c-Al 2 O 3 was numerically evaluated and the alumina phase transformation (c-Al 2 O 3 ?a-Al 2 O 3 ) was also studied. The temperature ranges revealed the appearance of metastable phases (h-Al 2 O 3 ). Complete oxidation of particles can be obtained at 1,300°C in \1 h, although this also takes place at lower temperatures if enough oxidation time is used. Activation energy of oxidation process at high temperature was also estimated, taking a value of 334 kJ/mol. High temperature oxidation causes the formation of hollow alumina spheres, without any aluminium left inside them.

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Section: Resultsmentioning

confidence: 86%

Oxidation of Micro-Sized Aluminium Particles: Hollow Alumina Spheres

et al. 2013

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“…The trends were determined by fitting the data (y) with time (t) to a simple power law of € y = (k⋅ t) n , where k is the growth rate constant and n is the temporal exponent. The kinetics for external oxide scale thickness (OST) deviated from classic parabolic growth, time 1/2 and followed a cubic rate law, time 1/3 , which may be attributed to significant grain growth within the Cr 2 O 3 oxide [12]. In contrast, a parabolic rate law was determined for the average planar extension of the Al 2 O 3 fingers (AFD) from the oxide/metal interface into the metal.…”

Section: Resultsmentioning

confidence: 94%

Oxidation and the Effects of High Temperature Exposures on Notched Fatigue Life of an Advanced Powder Metallurgy Disk Superalloy

et al. 2012

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Oxidation and the effects of high temperature exposures on notched fatigue life were considered for a powder metallurgy processed supersolvus heat-treated ME3 disk superalloy. The isothermal static oxidation response at 704 °C, 760 °C, and 815 °C was consistent with other chromia forming nickel-based superalloys: a TiO 2 -Cr 2 O 3 external oxide formed with a branched Al 2 O 3 internal subscale that extended into a recrystallized γ'-dissolution layer. These surface changes can potentially impact disk durability, making layer growth rates important. Growth of the external scales and γ'dissolution layers followed a cubic rate law, while Al 2 O 3 subscales followed a parabolic rate law. Cr-rich M 23 C 6 carbides at the grain boundaries dissolved to help sustain Cr 2 O 3 growth to depths about 12 times thicker than the scale.The effect of prior exposures was examined through notched low cycle fatigue tests performed to failure in air at 704 °C. Prior exposures led to pronounced debits of up to 99 % in fatigue life, where fatigue life decreased inversely with exposure time. Exposures that produced roughly equivalent 1 µm thick external scales at the various isotherms showed statistically equivalent fatigue lives, establishing that surface damage drives fatigue debit, not exposure temperature. Fractographic evaluation indicated the failure mode for the pre-exposed specimens involved surface crack initiations that shifted with exposure from predominately single intergranular initiations with transgranular propagation to multi-initiations from the cracked external oxide with intergranular propagation. Weakened grain boundaries at the surface resulting from the M 23 C 6 carbide dissolution are partially responsible for the intergranular cracking. Removing the scale and subscale while leaving a layer where M 23 C 6 carbides were dissolved did not lead to a significant fatigue life improvement, however, also removing the M 23 C 6 carbide dissolution layer led to nearly full recovery of life, with a transgranular initiation typical to that observed in unexposed specimens.

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“…It is seen that the kinetics are sub-parabolic, with m ranging from 0.24-0.36, and near the reported cubic rate [2,3,9]. The cubic rate constant, affected by grain growth [2,9,23,24,25], is then determined according to:…”

Section: Comparative Oxidative Life Of Ysz Coatings On Bulk Ti 2 Alc mentioning

confidence: 97%

Oxidative durability of TBCs on Ti2AlC MAX phase substrates

Smialek

Harder

Garg

2016

Surface and Coatings Technology

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Air plasma spray (APS) and plasma-spray-physical vapor deposition (PS-PVD) yttria-stabilized zirconia (YSZ) thermal barrier coatings (TBC),~80-100 μm thick, were produced on a commercial Ti 2 AlC MAX phase compound. They were oxidized in interrupted furnace tests for 500 h each, at five successive temperatures from 1100°-1300°C. The APS coating survived 2400 accumulated hours, failing catastrophically after 500 h at 1300°C. Porosity, large cracks, sintering, and high monoclinic YSZ phase contents were seen as primary degradation factors. The PS-PVD coating remained completely intact over 2500 total hours (65 cycles) including 500 h at 1300°C, exhibiting only fine porosity and microcracking, with less monoclinic. These Ti 2 AlC systems achieved a minimum α-Al 2 O 3 scale thickness of 29 and 35 μm, respectively, as compared to~6 ± 2 μm on average at failure for conventional bond coats on superalloys. Accordingly, times predicted from thermogravimetric analyses (TGA) of oxidation kinetics project an improvement factor of~25-50× for the time to achieve these scale thicknesses at a given temperature. Extreme oxidative TBC durability is achieved because the thermal expansion coefficient of Ti 2 AlC is only slightly different than those for α-Al 2 O 3 and YSZ. The strain energy term driving scale and TBC failure is therefore believed to be fundamentally diminished from the large compressive stress produced by higher expansion superalloys.Published by Elsevier B.V.

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Correlation between the Microstructure, Growth Mechanism, and Growth Kinetics of Alumina Scales on a FeCrAlY Alloy

Cited by 115 publications

References 34 publications

Oxidation of Micro-Sized Aluminium Particles: Hollow Alumina Spheres

Oxidation of Micro-Sized Aluminium Particles: Hollow Alumina Spheres

Oxidation and the Effects of High Temperature Exposures on Notched Fatigue Life of an Advanced Powder Metallurgy Disk Superalloy

Oxidative durability of TBCs on Ti2AlC MAX phase substrates

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