LaCrO3 composite coatings for AISI 444 stainless steel solid oxide fuel cell interconnects

Acchar, Wilson; Barreto, Ledjane Silva; Paes Junior, Herval Ramos; Cruz, Clawsio Rogerio; Feistauer, Eduardo Etzberger

doi:10.1590/S1516-14392012005000140

Abstract

Doped lanthanum chromite-based ceramics are the most widely used interconnector material in solid fuel cells (SOFC) since they exhibit significant electrical and thermal conductivity, substantial corrosion resistance and adequate mechanical strength at ambient and high temperatures. The disadvantage of this material is its high cost and poor ductility. The aim of this study is to determine the mechanical and oxidation behavior of a stainless steel (AISI 444) with a LaCrO3 deposition on its surface obtained through spray pyrolisis. Coated and pure AISI 444 materials were characterized by mechanical properties, oxidation behavior, X-ray diffraction and scanning electronic microscopy. Results indicated that the coated material displays better oxidation behavior in comparison to pure stainless steel, but no improvement in mechanical strength. Both materials indicate that deformation behavior depends on testing temperatures.

lanthanum chromite; interconnector; oxidation; mechanical strength; AISI 444

LaCrO₃ composite coatings for AISI 444 stainless steel solid oxide fuel cell interconnects

Wilson AccharI, ^* * e-mail: acchar@dfte.ufrn.br ; Ledjane Silva Barreto^II; Herval Ramos Paes Junior^III; Clawsio Rogerio Cruz^I; Eduardo Etzberger Feistauer^II

^IPostgraduate Program of Science and Materials Engineering, Federal University of Rio Grande do Norte - UFRN, CEP 59072-970, Natal, RN, Brazil

^IIPostgraduate Program of Science and Materials Engineering, Federal University of Sergipe - UFS, CEP 49000-100, Sergipe, SE, Brazil

^IIILaboratório de Materiais Avançados, Universidade Estadual do Norte Fluminense - UENF, CEP 28013-602, Campos dos Goytacazes, RJ, Brasil

ABSTRACT

Doped lanthanum chromite-based ceramics are the most widely used interconnector material in solid fuel cells (SOFC) since they exhibit significant electrical and thermal conductivity, substantial corrosion resistance and adequate mechanical strength at ambient and high temperatures. The disadvantage of this material is its high cost and poor ductility. The aim of this study is to determine the mechanical and oxidation behavior of a stainless steel (AISI 444) with a LaCrO₃ deposition on its surface obtained through spray pyrolisis. Coated and pure AISI 444 materials were characterized by mechanical properties, oxidation behavior, X-ray diffraction and scanning electronic microscopy. Results indicated that the coated material displays better oxidation behavior in comparison to pure stainless steel, but no improvement in mechanical strength. Both materials indicate that deformation behavior depends on testing temperatures.

Keywords: lanthanum chromite, interconnector, oxidation, mechanical strength, AISI 444

1. Introduction

Solid oxide fuel cells (SOFC) are a new source of clean energy for electrical generation¹. Planar cells consist of several cell units separated by an interconnector², whose main role is as an electrical connection between the cells. The interconnector must be also compatible with all cell components³ and stable with respect to oxiding and reducing gases, present in the SOFC. Typical requirements of an interconnect material are: high electronic conductivity, chemical stability, thermal expansion match to other cell components, significant mechanical strength and- thermal conductivity, low manufacturing and material costs^4,5.Lanthanum chromite (LaCrO₃) doped with calcium, strontium and magnesium is the most viable material, since it exhibits relatively high electronic conductivity in both fuel and oxidant atmospheres, moderate stability in fuel cell environments and good compatibility with other cell components in terms of phase, microstructure and thermal expansion^1,4,16,17. Reducing cell operating temperature from 1000 °C to 800 °C makes using metallic materials as interconnects an attractive alternative. The main advantages of metallic over ceramic interconnects are lower manufacturing costs⁶ and higher deformation capacity⁷. Chromium- and iron-based alloys are the most widely investigated metallic interconnect materials^5,8,9. The main drawbacks limiting use of these materials are: low oxidation resistance over the projected service lifetime (40000 h) at high operating temperature¹⁰ and ability to develop oxide scales with sufficiently high electronic conductivity⁹; Cr volatilization, and limited strength at operating cell temperatures⁸. Studies have proposed the use of a coating on the metallic interconnector material as an oxidation layer^7,13,14,15. Different techniques have focused on developing protective coatings for steel interconnects¹¹, such as, sol-gel, chemical vapor deposition¹², pulsed laser deposition, plasma spraying¹⁴ and screen-printing¹³. Applying Co/LaCrO₃ coating to AISI 430 stainless steel improves oxidation resistance. However, silica networks that form at the metal-scale interface result in scale and pore formation in Co-LaCrO₃-coated specimens⁷. Calcium or strontium-doped lanthanum chromite thin film layers are successfully manufactured using a dipping technique, but oxidation performance was not adequate⁸. A protection layer of MnCo_1.9Fe_0.1O₄ spinel can be densified on ferritic steels though reactive sintering. Results show excellent structural and thermo stability of these spinel protection layers; however, the thermal expansion match between the spinel and LaSrCoFe contact layer seems to be insufficient for thermal cycling¹².

The present study describes the thermo-mechanical effect of LaCrO₃ as a protective coating on AISI 444 stainless steel.

2. Experimental procedure

LaCrO₃ thin films were deposited on the AISI 444 substrate (ferritic stainless steel, from Arcelor Mittal) using a spray-pyrolysis technique (Figure 1). Polished metallic substrates were ultrasonically cleaned in acetone for 20 minutes, rinsed in distilled water, soaked for 30 s in acetone and then dried.

Precursor solutions for the LaCrO₃ thin film coating were prepared from starting materials of lanthanum nitrate hexahydrate (La(NO₃)_{3 .} 6 H₂O) and chromium tri-oxide (CrO₃) (Aldrich Chemicals). Precursor concentration was 0.05 M. Adequate amounts of starting materials were dissolved in distilled water and isopropyl alcohol. Operating conditions for spray pyrolisis used in this investigation are shown in Table 1. Finally, the resulting thin films were heat-treated at 900 °C for 120 minutes in a labor furnace (EDG, Brazil).

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The oxidation treatment was examined at 850 and 900 °C for 1.5 × 10³ minutes in air. For comparison with non-coated AISI 444, thin film coated and non-coated substrates were oxidized under the same conditions.

Crystallization and oxidation behavior were analyzed with X-ray diffraction (XRD 6000, Shimadzu) in order to study the stability of both materials at high temperatures.

Mechanical strength of the sintered specimens (average of five bodies for each value) was measured in 20 × 10 × 1.2 mm samples on a universal testing machine (Zwick-Roell, Germany) in three-point bending tests at a constant crosshead speed of 0.5 mm/min under high and ambient temperatures.

Microstructural aspects of surface and cross-sectional morphology for coated land non-coated materials were examined using optical and scanning electron microcopy (Shimadzu SSX-550).

3. Results and discussion

Table 2 displays the chemical composition of the stainless steel studied. As expected, the material consists primarily of iron (bal.), carbon (0,025 wt. (%)), manganese (1,0 wt. (%)), phosphorus (0,040 wt. (%)), sulfur (0,030 wt. (%)), silicon (1,00 wt. (%)), nickel (1,00 wt. (%)) and chromium (17.55 wt. (%)). Figure 2 shows the X-ray diffraction pattern of both investigated materials. As expected, pure and coated AISI 444 material indicates the presence of the Fe-Cr phase (AISI 444) and LaCrO_3, respectively. No evidence of other phases was found. Figure 3 depicts the microstructural aspects of both materials. As shown, the LaCrO₃ material presents a homogeneous grain size distribution, with a grain size of approximately 0.7 µm. Microstructural aspects of the transverse cross-section of AISI 444 with LaCrO₃ deposition are presented in Figure 4. The spray pyrolysis process produced a regular LaCrO₃ layer along the surface with a layer depth of approximately 100 µm.

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Figure 4 shows mapping of the principal elements across the transverse section of stainless steel with lanthanum chromite deposition. Results indicate the constant presence of Cr in the stainless steel, along the interface and in deposition. As expected, the concentration of lanthanum is low in the steel region and high in the deposited layer. The amount of Fe element is elevated in the steel and not present in the coated region. Figure 5 presents the strength behavior at ambient and high-temperatures. Both materials exhibited very similar behavior, regardless of temperature. Strength values of the composite materials at ambient temperature are higher when compared to LaCrO₃ (180-260 MPa)⁴, but similar at 900 °C (50-100 MPa)¹⁰. At 900 °C, the materials display significantly higher deformation values in comparison to ambient temperature, which is characteristic of metallic behavior (Figure 5). No significant difference was found between materials, which may indicate that deposition has notable effect on strength behavior of metallic substrate. Similar strength behavior was observed for creeping tests in high-Cr ferritic steels⁶.

Figure 6 illustrates the oxidation behavior of the investigated materials. Results demonstrated that deposition of LaCrO₃ improved oxidation resistance of pure AISI 444, regardless of oxidation temperature. Weight gain of coated materials was significantly lower in relation to stainless steel. Application of (La,Sr)FeO₃ protection layers on ferritic steel also resulted in some improvement in oxidation resistance¹⁵.

Figure 7 shows the X-ray diffraction patterns of stainless steel and the coated material after oxidation tests. Analyses indicated the AISI 444 material exhibits formation of a new crystalline phase (Cr₂O₃) at high temperatures. The presence of Cr₂O₃ and similar oxidation behavior was also observed in the literature^8,13. Furthermore, the coated material displays a new crystalline phase (Fe-Cr), which is evidence of Fe diffusion from the steel across the steel/LaCrO₃ interface. Analogous results were also observed elsewhere⁷. No presence of Fe₂O₃ was identified in X-ray diffraction patterns. Figure 8 shows a surface defect on the AISI 444 surface produced during spray pyrolisis. The absence of the protection layer (LaCrO₃) on the metal base increases steel oxidation. The coated material demonstrates an abrupt increase in mass gain during analysis (Figure 8). The spray pyrolisis process must be improved in order to avoid such surface defects.

Further studies are still underway in order to optimize the quality of the spray pyrolisis process and its consequent properties. Creep tests should be also performed.

4. Conclusions

Lanthanum chromite thin film layers are successfully manufactured using a spray pyrolisis technique from precursor solutions. Nevertheless, this process needs to be improved in order to avoid the deposition defect observed on the surface and resulting decrease in the oxidation resistance. A denser microstructure is observed for the LaCrO₃ thin film on the AISI 4444 substrate. The use of LaCrO₃ coating on the AISI 444 stainless steel significantly improves oxidation resistance. Thermo-mechanical properties of the composite are strongly dependent on the temperature. The material shows substantial strengths and low deformation values at ambient temperature. Increasing test temperature results in a loss of mechanical resistance and greater deformation.

Acknowledgement

The authors would like to thank the CNPq and FINEP for their financial support.

Received: March 22, 2012

Revised: August 3, 2012

1. Stover D, Buchkremer HP, Titz F and Menzler NF. Solid oxide fuel cells (SOFCS). The Everlasting Challenge for High-performance Ceramics. In: Proceedings of the 2^nd International Congress on Ceramics; 2008; Verona. Verona; 2008.
2. Subhash C and Kendall K. High Temperature Solid Oxide Fuel Cells: Fundamentals, Design and Application. Elsevier; 2003.
3. Zhu WZ and Deevi SC. Development of interconnect materials for solid oxide fuel cells. Materials & Science Engineering A 2003; 348:227-243. http://dx.doi.org/10.1016/S0921-5093(02)00736-0
4. Sammes NM and Ratnaraj R. High temperature mechanical properties of La_1-xSr_xCr_{1- y}Co_yO₃ for SOFC interconnect. Journal of Materials Science 1995; 30:4523-4526. http://dx.doi.org/10.1007/BF01153057
5. Fergus JW. Metallic interconnects for solid oxide fuel cells. Materials Science & Engineering A 2005; 397:271-283. http://dx.doi.org/10.1016/j.msea.2005.02.047
6. Froitzheim J, Meier GH, Niewolak L, Ennis PJ, Hattendorf H, Singheiser L et al. Development of high strength ferritic steel for interconnect application in SOFCs. Journal of Power Sources 2008; 178:163-173. http://dx.doi.org/10.1016/j.jpowsour.2007.12.028
7. Shaigan N, Qu W, Ivey DG and Chen W. A review of recent progress in coating, surface modifications and alloy developments for solid oxide fuel cell ferritic stainless steel interconnects. Journal of Power Sources 2010; 195:1529-1542. http://dx.doi.org/10.1016/j.jpowsour.2009.09.069
8. Lee EA, Lee S, Hwang HJ and Moon JW. Sol-gel derived (La_0.8M_0.2)CrO₃(M=Ca,Sr) coating layer on stainless-steel substrate for use as a separator in intermediate temperature solid fuel cell. Journal of Power Sources 2006; 157:709-713. http://dx.doi.org/10.1016/j.jpowsour.2005.12.030
9. Horita T, Xiong Y, Yamaji K, Sakai N and Yokokawa H. Stability of Fe-Cr alloy interconnects under CH₄-H₂O atmosphere for SOFCS. Journal of Power Sources 2003; 118:35-43. http://dx.doi.org/10.1016/S0378-7753(03)00058-2
10. Sammes NM, Ratnaraj R and Fee MG. The effect of sintering on the mechanical properties of SOFC ceramic interconnect materials. Journal of Materials Science. 1994; 29:4319-24. http://dx.doi.org/10.1007/BF00414217
11. Shaigan N, Ivey DG and Chen W. Co/LaCrO₃ composite coating for AISI 430 stain- less solid oxide fuel cell interconnectors. Journal of Power Sources 2008; 185:331-337. http://dx.doi.org/10.1016/j.jpowsour.2008.06.065
12. Montero X, Tietz, F, Sebold D, Buchkremer HP, Ringuede A, Cassir M et al. MnCo_1.9Fe_0.1O₄ spinel protection layer on commercial ferritic steels for interconnect applications in solid oxide fuel cells. Journal of Power Sources. 2008; 184:172-179. http://dx.doi.org/10.1016/j.jpowsour.2008.05.081
13. Chu CL, Lee J, Lee TH and Cheng YN. Oxidation behavior of metallic interconnect coated with La-Sr-Mn film by screen painting and plasma sputtering. International Journal of Hydrogen Energy. 2009; 34:422-434. http://dx.doi.org/10.1016/j.ijhydene.2008.09.091
14. Zhen YD, Jiang SP, Zhang S and Tan V. Interaction between metallic interconnect And constituent oxides of (La,Sr)MnO₃ coating of solid oxide fuel cells. Journal of the European Ceramic Society 2006; 26:3253-3264. http://dx.doi.org/10.1016/j.jeurceramsoc.2005.10.002
15. Yang Z, Xia GG, Maupin GD and Stevenson JW. Conductive protection layers on oxidation resistant alloys for SOFC interconnect applications. Surface & Coating Technology 2006; 201:4476-4483. http://dx.doi.org/10.1016/j.surfcoat.2006.08.082
16. Fergus JW. Lanthanum chromite-based materials for solid oxide fuel cell interconnects. Solid State Ionics. 2004; 171:1-15. http://dx.doi.org/10.1016/j.ssi.2004.04.010
17. Badwal SPS. Stability of solid oxide fuel cell components. Solid State Ionics. 2001; 143:39-46. http://dx.doi.org/10.1016/S0167-2738(01)00831-1

*

e-mail:

acchar@dfte.ufrn.br

Publication Dates

Publication in this collection
23 Oct 2012
Date of issue
Dec 2012

History

Received
22 Mar 2012
Accepted
03 Aug 2012

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] 1. Stover D, Buchkremer HP, Titz F and Menzler NF. Solid oxide fuel cells (SOFCS). The Everlasting Challenge for High-performance Ceramics. In: Proceedings of the 2^nd International Congress on Ceramics; 2008; Verona. Verona; 2008.

[2] 2. Subhash C and Kendall K. High Temperature Solid Oxide Fuel Cells: Fundamentals, Design and Application. Elsevier; 2003.

[3] 3. Zhu WZ and Deevi SC. Development of interconnect materials for solid oxide fuel cells. Materials & Science Engineering A 2003; 348:227-243. http://dx.doi.org/10.1016/S0921-5093(02)00736-0

[4] 4. Sammes NM and Ratnaraj R. High temperature mechanical properties of La_1-xSr_xCr_{1- y}Co_yO₃ for SOFC interconnect. Journal of Materials Science 1995; 30:4523-4526. http://dx.doi.org/10.1007/BF01153057

[5] 5. Fergus JW. Metallic interconnects for solid oxide fuel cells. Materials Science & Engineering A 2005; 397:271-283. http://dx.doi.org/10.1016/j.msea.2005.02.047

[6] 6. Froitzheim J, Meier GH, Niewolak L, Ennis PJ, Hattendorf H, Singheiser L et al. Development of high strength ferritic steel for interconnect application in SOFCs. Journal of Power Sources 2008; 178:163-173. http://dx.doi.org/10.1016/j.jpowsour.2007.12.028

[7] 7. Shaigan N, Qu W, Ivey DG and Chen W. A review of recent progress in coating, surface modifications and alloy developments for solid oxide fuel cell ferritic stainless steel interconnects. Journal of Power Sources 2010; 195:1529-1542. http://dx.doi.org/10.1016/j.jpowsour.2009.09.069

[8] 8. Lee EA, Lee S, Hwang HJ and Moon JW. Sol-gel derived (La_0.8M_0.2)CrO₃(M=Ca,Sr) coating layer on stainless-steel substrate for use as a separator in intermediate temperature solid fuel cell. Journal of Power Sources 2006; 157:709-713. http://dx.doi.org/10.1016/j.jpowsour.2005.12.030

[9] 9. Horita T, Xiong Y, Yamaji K, Sakai N and Yokokawa H. Stability of Fe-Cr alloy interconnects under CH₄-H₂O atmosphere for SOFCS. Journal of Power Sources 2003; 118:35-43. http://dx.doi.org/10.1016/S0378-7753(03)00058-2

[10] 10. Sammes NM, Ratnaraj R and Fee MG. The effect of sintering on the mechanical properties of SOFC ceramic interconnect materials. Journal of Materials Science. 1994; 29:4319-24. http://dx.doi.org/10.1007/BF00414217

[11] 11. Shaigan N, Ivey DG and Chen W. Co/LaCrO₃ composite coating for AISI 430 stain- less solid oxide fuel cell interconnectors. Journal of Power Sources 2008; 185:331-337. http://dx.doi.org/10.1016/j.jpowsour.2008.06.065

[12] 12. Montero X, Tietz, F, Sebold D, Buchkremer HP, Ringuede A, Cassir M et al. MnCo_1.9Fe_0.1O₄ spinel protection layer on commercial ferritic steels for interconnect applications in solid oxide fuel cells. Journal of Power Sources. 2008; 184:172-179. http://dx.doi.org/10.1016/j.jpowsour.2008.05.081

[13] 13. Chu CL, Lee J, Lee TH and Cheng YN. Oxidation behavior of metallic interconnect coated with La-Sr-Mn film by screen painting and plasma sputtering. International Journal of Hydrogen Energy. 2009; 34:422-434. http://dx.doi.org/10.1016/j.ijhydene.2008.09.091

[14] 14. Zhen YD, Jiang SP, Zhang S and Tan V. Interaction between metallic interconnect And constituent oxides of (La,Sr)MnO₃ coating of solid oxide fuel cells. Journal of the European Ceramic Society 2006; 26:3253-3264. http://dx.doi.org/10.1016/j.jeurceramsoc.2005.10.002

[15] 15. Yang Z, Xia GG, Maupin GD and Stevenson JW. Conductive protection layers on oxidation resistant alloys for SOFC interconnect applications. Surface & Coating Technology 2006; 201:4476-4483. http://dx.doi.org/10.1016/j.surfcoat.2006.08.082

[16] 16. Fergus JW. Lanthanum chromite-based materials for solid oxide fuel cell interconnects. Solid State Ionics. 2004; 171:1-15. http://dx.doi.org/10.1016/j.ssi.2004.04.010

[17] 17. Badwal SPS. Stability of solid oxide fuel cell components. Solid State Ionics. 2001; 143:39-46. http://dx.doi.org/10.1016/S0167-2738(01)00831-1