Thermal Diffusivity of TBC Layers of RE2Zr2O7 Type

Grzegorz Moskal

doi:10.4028/www.scientific.net/DDF.312-315.445

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HomeDefect and Diffusion ForumDefect and Diffusion Forum Vols. 312-315Thermal Diffusivity of TBC Layers of RE2Zr2O7 Type

Thermal Diffusivity of TBC Layers of RE₂Zr₂O₇ Type

Abstract:

The paper presents the results of basic thermal properties of thermal barrier coatings on the base of rare earth zirconate of type Gd2Zr2O7, deposited by the air plasma spraying (APS) method. Measurements of thermal diffusivity with the laser-flash method were performed within the temperature range of 25°C-1100°C with two and ten hours of annealing. The measurements were performed on the single-layer (AMS 5599 alloy), double-layer (AMS 5599 alloy + NiCrAlY interlayer) and three-layer samples (AMS 5599 alloy + NiCrAlY interlayer + ceramic layer of RE2Zr2O7). By using the NETZSCH Proteus software and the results for the single-layer sample, thermal diffusivity of the interlayer itself was determined by means of the double-layer model. A similar method was used to determine the thermal diffusivity of the ceramic layer. The obtained results showed lower thermal diffusivity and thermal conductivity for the new type of coatings in comparison with the standard zirconium concerning TBCs. Those results are slightly different compared with the results obtained for the initial powders, which indicates a crucial role of the ceramic layer microstructure (architecture of cracks and porosity).

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Periodical:

Defect and Diffusion Forum (Volumes 312-315)

Pages:

445-450

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https://doi.org/10.4028/www.scientific.net/DDF.312-315.445

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Online since:

April 2011

Authors:

Grzegorz Moskal

Keywords:

Gd Zirconates, TBC, Thermal Property

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References

[1] Golosnoy I.O., Cipitria A., Clyne T.W.: J. Thermal Spray Technology Vol. 18 (2009), p.809.

Google Scholar

[2] Zhu D.M., Miller R. A: Journal of Thermal Spray Technology Vol. 9 (2000), p.175.

Google Scholar

[3] Renteria A.F., Saruhan B.: Journal of European Ceramic Society Vol. 26 (2006), p.2249.

Google Scholar

[4] Rahaman M.N., Gross J.R., Dutton R.E., Wang H.: Acta Materiallia Vol. 54 (2006), p.1615.

Google Scholar

[5] McPherson R.: Thin Solid Films Vol. 112 (1984), p.89.

Google Scholar

[6] Maloney MJ.: US Patent, 6, 117, 560; (2000).

Google Scholar

[7] Maloney MJ.: European Patent Application, EP 0 992 603 A1; (2000).

Google Scholar

[8] Vassen R et al: Journal of American Ceramic Society Vol. 83 (2000), p. (2023).

Google Scholar

[9] Wu J, et al.: Journal of American Ceramic Society Vol. 85 (2002), p.3031.

Google Scholar

[10] Maloney MJ.: US Patent Application, 20030049470 A1, (2003).

Google Scholar

[11] Klemens PG.: Proc Phys Soc London A Vol. 86 (1955), p.1113.

Google Scholar

[12] Suresh G. et al.: Journal of Nuclear Materials Vol. 249 (1997), p.259.

Google Scholar

[13] Moskal G.: Materials Science (in polish) – in press.

Google Scholar

[14] Wu J.: Journal of Materials Research Vol. 17 (2002), p.3193.

Google Scholar

[15] Slack G.A.: in Solid State Physics, edited by H. Ehrenreich, F. Seitz, and D. Turnbull (Academic Publishers, New York, 1979), Vol. 34, p.1.

Google Scholar

[16] Roufosse M.C., Klemen P.G.: Journal of Geophysics Research Vol. 79 (1974), p.703.

Google Scholar

[17] Subramanian M.A., Sleight A.W.: in Handbook on the Physics and Chemistry of Rare Earths, edited by K.A. Gschneider and L. Erying (Elsevier Science Publishers, Oxford, U.K., 1993), Vol. 16, p.225.

Google Scholar