Ceramic Coating Based on La, Sr and Co on Ferritic Stainless Steel for ITSOFC Interconnects

Matias de Angelis Korb; Raimundo Nonato Ferreira Linhares Junior; Eduardo Etzberger  Feistauer; Ledjane Silva Barreto; Vânia Caldas de Sousa; Iduvirges Lourdes Müller; Célia de Fraga Malfatti

doi:10.4028/www.scientific.net/MSF.727-728.522

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HomeMaterials Science ForumMaterials Science Forum Vols. 727-728Ceramic Coating Based on La, Sr and Co on Ferritic...

Ceramic Coating Based on La, Sr and Co on Ferritic Stainless Steel for ITSOFC Interconnects

Abstract:

Ferritic stainless steels have been used to produce interconnects for intermediate temperature solid oxide fuel cells (ITSOFC) due to their appropriate properties. Ferritic stainless steel presents mechanical stability, much higher thermal and electronic conductivities; significantly lower cost, and mechanical resistance than austenitic steels. Besides, it presents a thermal expansion coefficient compatible with the other materials of the cell components. However, in the range of this device operating temperature (600 °C 800 °C) it can occur the formation of poorly conducting oxide (Cr₂O₃) reducing the fuel cell performance. The aim of this work was to obtain oxide coatings starting with La, Sr and Co nitrates applied by spray-pyrolysis technique on a stainless steel AISI 430 substrate. The coatings obtained were characterized by X-ray diffraction and scanning electron microscopy/energy dispersive spectroscopy. The oxidation resistance of the ferritic stainless steel, coated with a perovskite (La_0,6Sr_0,4CoO₃) film, was investigated by isothermal oxidation. The results showed that the coating obtained promoted the increase of the ferritic stainless steel oxidation resistance. However, after the oxidation test, it was observed a Cr enrichment and a very pronounced Sr enrichment, near to the alloy/coating interface, which can be associate to the decomposition of La_0,6Sr_0,4CoO₃ film.

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Periodical:

Materials Science Forum (Volumes 727-728)

Pages:

522-527

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.727-728.522

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Online since:

August 2012

Authors:

Matias de Angelis Korb, Raimundo Nonato Ferreira Linhares Junior, Eduardo Etzberger Feistauer, Ledjane Silva Barreto, Vânia Caldas de Sousa, Iduvirges Lourdes Müller, Célia de Fraga Malfatti

Keywords:

Coating, Ferritic Stainless Steel (FSS), Interconnector, Spray Pyrolysis

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References

[1] T. Brylewski, M. Nanki, T. Maruyama and K. Przybylski: Solid State Ionics Vol. 143 (2001), p.131.

Google Scholar

[2] W. Qu, L. Li and D.G. Ivey: Journal of Power Sources Vol. 138 (2004), p.162.

Google Scholar

[3] G. Cabouro, G. Caboche, S. Chevalier and P. Piccardo: Journal of Power Sources Vol. 156 (2006), p.39.

Google Scholar

[4] X. Chen, P. Y. Hou, C. P. Jacobson, S. J. Visco and L. C. Jonghe: Solid State Ionics Vol. 176(2005), p.425.

Google Scholar

[5] Z. Yang, G.G. Xia, G.D. Maupin and J.W. Stevenson: Surface & Coatings Technology Vol. 201 (2006), p.4476.

Google Scholar

[6] J. W. Fergus: Materials Science and Engineering Vol. A397 (2005), p.271.

Google Scholar

[7] D. Chatterjee and S. Biswas: International Journal of Hydrogen Energy Vol. 36 (2011), p.4530.

Google Scholar

[8] P. Piccardo, P. Gannon, S. Chevalier, M. Viviani, A. Barbucci, G. Caboche, R. Amendola and S. Fontana: Surface & Coatings Technology Vol. 202 (2007), p.1221.

DOI: 10.1016/j.surfcoat.2007.07.096

Google Scholar

[9] H. Kurokawa, C.P. Jacobson, L. C. Jonghe and S. J. Visco: Solid State Ionics Vol. 178 (2007), p.287.

Google Scholar

[10] S.M.C. Fernandes and L.V. Ramanathan: Materials Research Vol. 7 (2004), p.135.

Google Scholar

[11] W.J. Quadakkers, H. Greiner, M. Hänsel, A. Pattanaik, A.S. Khanna and W. Malléner: Solid State Ionics Vol. 91 (1996), p.55.

Google Scholar