Details of Research Outputs

TitleEffect of anode calcination on the performance and redox stability of low-temperature solid oxide fuel cells prepared via impregnation
Author (Name in English or Pinyin)
Ni, Chengsheng1; Zhang, Yang1; Huang, Xiubing2; Zou, Jing3; Zhang, Guan4; Ni, Jiupai1
Date Issued2017-12-28
Firstlevel Discipline能源科学技术
Education discipline科技类
Published range国外学术期刊
Volume Issue Pagesv 42,n 52,p30760-30768
[1] Minh, N.Q., Ceramic fuel-cells. J Am Ceram Soc 76 (1993), 563–588.
[2] Ni, C., Feng, J., Cui, J., Zhou, J., Ni, J., An n-type oxide Fe0.5Mg0.25Ti0.25Nb0.9Mo0.1O4-δ for both cathode and anode of a solid oxide fuel cell. J Electrochem Soc 164 (2017), F283–F288.
[3] Park, S., Vohs, J.M., Gorte, R.J., Direct oxidation of hydrocarbons in a solid-oxide fuel cell. Nature 404 (2000), 265–267.
[4] Ni, C.S., Vohs, J., Gorte, R.J., Irvine, J.T.S., Fabrication and characterisation of a large-area solid oxide fuel cell based on dual tape cast YSZ electrode skeleton supported YSZ electrolyte with Vanadate and Ferrite perovskite- impregnated anode and cathode. J Mater Chem A 2 (2014), 19150–19155.
[5] Lu, L., Ni, C., Cassidy, M., Irvine, J.T.S., Demonstration of high performance in a perovskite oxide supported solid oxide fuel cell based on La and Ca co-doped SrTiO3. J Mater Chem A 4 (2016), 11708–11718.
[6] Sholklapper, T.Z., Kurokawa, H., Jacobson, C.P., Visco, S.J., De Jonghe, L.C., Nanostructured solid oxide fuel cell electrodes. Nano Lett 7 (2007), 2136–2141.
[7] Singh, B., Ghosh, S., Aich, S., Roy, B., Low temperature solid oxide electrolytes (LT-SOE): a review. J Power Sources 339 (2017), 103–135.
[8] Ni, C.S., Zhang, D.F., Ni, C.Y., Wang, Z.M., Ruddlesden–Popper nickelate as coating for chromia-forming stainless steel. Int J Hydrogen Energy 39 (2014), 13314–13319.
[9] Wachsman, E.D., Lee, K.T., Lowering the temperature of solid oxide fuel cells. Science 334 (2011), 935–939.
[10] Gao, Z., Mogni, L.V., Miller, E.C., Railsback, J.G., Barnett, S.A., A perspective on low-temperature solid oxide fuel cells. Energy Environ Sci 9 (2016), 1602–1644.
[11] Ishihara, T., Matsuda, H., Takita, Y., Doped LaGaO3 perovskite type oxide as a new oxide ionic conductor. J Am Chem Soc 116 (1994), 3801–3803.
[12] Morales, M., Roa, J.J., Tartaj, J., Segarra, M., A review of doped lanthanum gallates as electrolytes for intermediate temperature solid oxides fuel cells: from materials processing to electrical and thermo-mechanical properties. J Eur Ceram Soc 36 (2016), 1–16.
[13] Zhan, Z., Bierschenk, D.M., Cronin, J.S., Barnett, S.A., A reduced temperature solid oxide fuel cell with nanostructured anodes. Energy Environ Sci 4 (2011), 3951–3954.
[14] Da, H., Liu, X., Zeng, F., Qian, J., Wu, T., Zhan, Z., A micro-nano porous oxide hybrid for efficient oxygen reduction in reduced-temperature solid oxide fuel cells. Sci Rep, 2, 2012, 462.
[15] Gao, Z., Wang, H., Miller, E., Liu, Q., Senn, D., Barnett, S., Tape casting of high-performance low-temperature solid oxide cells with thin La0.8Sr0.2Ga0.8Mg0.2O3−δ electrolytes and impregnated nano anodes. ACS Appl Mater Interfaces 9 (2017), 7115–7124.
[16] Gao, Z., Miller, E.C., Barnett, S.A., A high power density intermediate-temperature solid oxide fuel cell with thin (La0.9Sr0.1)0.98(Ga0.8Mg0.2)O3-δ electrolyte and nano-scale anode. Adv Funct Mater 24 (2015), 5703–5709.
[17] Sun, H., Chen, Y., Chen, F., Zhang, Y., Liu, M., High-performance solid oxide fuel cells based on a thin La0.8Sr0.2Ga0.8Mg0.2O3−δ electrolyte membrane supported by a nickel-based anode of unique architecture. J Power Sources 301 (2016), 199–203.
[18] Fang, Q., Blum, L., Batfalsky, P., Menzler, N.H., Packbier, U., Stolten, D., Durability test and degradation behavior of a 2.5 kW SOFC stack with internal reforming of LNG. Int J Hydrogen Energy 38 (2013), 16344–16353.
[19] Papadam, T., Goula, G., Yentekakis, I.V., Long-term operation stability tests of intermediate and high temperature Ni-based anodes’ SOFCs directly fueled with simulated biogas mixtures. Int J Hydrogen Energy 37 (2012), 16680–16685.
[20] Wang, W., Gross, M.D., Vohs, J.M., Gorte, R.J., The stability of LSF-YSZ electrodes prepared by infiltration. J Electrochem Soc 154 (2007), B439–B445.
[21] Kim, S.J., Choi, M.-B., Park, M., Kim, H., Son, J.-W., Lee, J.-H., et al. Acceleration tests: degradation of anode-supported planar solid oxide fuel cells at elevated operating temperatures. J Power Sources 360 (2017), 284–293.
[22] Huang, P., Horky, A., Petric, A., Interfacial reaction between nickel oxide and lanthanum Gallate during sintering and its effect on conductivity. J Am Ceram Soc 82 (1999), 2402–2406.
[23] Klemenso, T., Thyden, K., Chen, M., Wang, H.J., Stability of Ni-yttria stabilized zirconia anodes based on Ni-impregnation. J Power Sources 195 (2010), 7295–7301.
[24] Liu, Z., Liu, B., Ding, D., Liu, M., Chen, F., Xia, C., Fabrication and modification of solid oxide fuel cell anodes via wet impregnation/infiltration technique. J Power Sources 237 (2013), 243–259.
[25] Huang, K., Wan, J.-H., Goodenough, J.B., Increasing power density of LSGM-based solid oxide fuel cells using new anode materials. J Electrochem Soc 148 (2001), A788–A794.
[26] Huang, K.Q., Tichy, R., Goodenough, J.B., Superior perovskite oxide-ion conductor; strontium- and magnesium-doped LaGaO3: III, Performance tests of single ceramic fuel cells. J Am Ceram Soc 81 (1998), 2581–2585.
[27] Liu, X., Meng, X., Han, D., Wu, H., Zeng, F., Zhan, Z., Impregnated nickel anodes for reduced-temperature solid oxide fuel cells based on thin electrolytes of doped LaGaO3. J Power Sources 222 (2013), 92–96.
[28] Sarantaridis, D., Atkinson, A., Redox cycling of Ni-Based solid oxide fuel cell anodes: a review. Fuel Cells 7 (2007), 246–258.
[29] Panthi, D., Choi, B., Tsutsumi, A., Performance improvement and redox cycling of a micro-tubular solid oxide fuel cell with a porous zirconia support. Int J Hydrogen Energy 40 (2015), 10588–10595.
[30] Monzón, H., Laguna-Bercero, M.A., Redox-cycling studies of anode-supported microtubular solid oxide fuel cells. Int J Hydrogen Energy 37 (2012), 7262–7270.
[31] Heo, Y.-H., Lee, J.-W., Lee, S.-B., Lim, T.-H., Park, S.-J., Song, R.-H., et al. Redox-induced performance degradation of anode-supported tubular solid oxide fuel cells. Int J Hydrogen Energy 36 (2011), 797–804.
[32] Ni, C., Irvine, J.T.S., Image analysis and modeling of the orientation of pores in a constrained film on a rigid substrate. J Am Ceram Soc 98 (2015), 2403–2410.
[33] Küngas, R., Kim, J.-S., Vohs, J.M., Gorte, R.J., Restructuring porous YSZ by treatment in hydrofluoric acid for Use in SOFC cathodes. J Am Ceram Soc 94 (2011), 2220–2224.
[34] Hong, J.E., Inagaki, T., Ida, S., Ishihara, T., Gur, T., Titania-added Ce0.6La0.4O2-δ for the buffer layer of high-performance solid oxide fuel cells using doped lanthanum Gallate electrolyte film. J Am Ceram Soc 95 (2012), 3588–3596.
[35] Lin, Y., Barnett, S.A., Co-firing of anode-supported SOFCs with thin La0.9Sr0.1Ga0.8Mg0.2O3 − δ electrolytes. Electrochem Solid-State Lett 9 (2006), A285–A288.
[36] Tan, Z., Ishihara, T., Sr(La)TiO3 anode substrate for low Ni diffusion in Sr- and Mg-Doped LaGaO3 film prepared with Co-Sintering method for intermediate temperature tubular type solid oxide fuel cells. J Electrochem Soc 164 (2017), F815–F820.
[37] Huang, K., Wan, J., Goodenough, J.B., Oxide-ion conducting ceramics for solid oxide fuel cells. J Mater Sci 36 (2001), 1093–1098.
[38] Huang, Y.Y., Ahn, K., Vohs, J.M., Gorte, R.J., Characterization of Sr-doped LaCoO3-YSZ composites prepared by impregnation methods. J Electrochem Soc 151 (2004), A1592–A1597.
[39] Atkinson, A., Barnett, S., Gorte, R.J., Irvine, J.T.S., McEvoy, A.J., Mogensen, M., et al. Advanced anodes for high-temperature fuel cells. Nat Mater 3 (2004), 17–27.
[40] Myung, J-h, Shin, T.H., Huang, X., Carins, G., Irvine, J.T.S., Enhancement of redox stability and electrical conductivity by doping various metals on ceria, Ce1−xMxO2−δ (M = Ni, Cu, Co, Mn, Ti, Zr). Int J Hydrogen Energy 40 (2015), 12003–12008.
[41] Shen, X., Kawabata, T., Sasaki, K., Redox-stable Sr0.9La0.1TiO3-supported SOFC single cells. Int J Hydrogen Energy 42 (2017), 6941–6949.
[42] Shen, X., Sasaki, K., Robust SOFC anode materials with La-doped SrTiO3 backbone structure. Int J Hydrogen Energy 41 (2016), 17044–17052.
[43] Sugimoto, J., Futamura, S., Kawabata, T., Lyth, S.M., Shiratori, Y., Taniguchi, S., et al. Ru-based SOFC anodes: preparation, performance, and durability. Int J Hydrogen Energy 42 (2017), 6950–6964.
[44] Li, K., Wang, X., Jia, L., Yan, D., Pu, J., Chi, B., et al. High performance Ni–Fe alloy supported SOFCs fabricated by low cost tape casting-screen printing-cofiring process. Int J Hydrogen Energy 39 (2014), 19747–19752.
[45] Brus, G., Miyoshi, K., Iwai, H., Saito, M., Yoshida, H., Change of an anode's microstructure morphology during the fuel starvation of an anode-supported solid oxide fuel cell. Int J Hydrogen Energy 40 (2015), 6927–6934.
[46] Buyukaksoy, A., Petrovsky, V., Dogan, F., Optimization of redox stable Ni-YSZ anodes for SOFCs by two-step infiltration. J Electrochem Soc 159 (2012), F841–F848.
[47] Jamil, Z., Ruiz-Trejo, E., Boldrin, P., Brandon, N.P., Anode fabrication for solid oxide fuel cells: electroless and electrodeposition of nickel and silver into doped ceria scaffolds. Int J Hydrogen Energy 41 (2016), 9627–9637.
Citation statistics
Cited Times [WOS]:0   [WOS Record]     [Related Records in WOS]
Document TypeJournal article
CollectionSchool of Humanities and Social Science
Corresponding AuthorNi, Chengsheng; Ni, Jiupai
1.College of Resources and Environment, Southwest University, Chongqing; 400716, China
2.Beijing Key Laboratory of Function Materials for Molecule & Structure Construction, School of Materials Science and Engineering, University of Science and Technology, Beijing; 100083, China
3.School of Humanities and Social Science, The Chinese University of Hong Kong, Shenzhen, Shenzhen; 518172, Hong Kong
4.School of Civil and Environmental Engineering, Harbin Institute of Technology, Shenzhen, Shenzhen; 518055, China
Recommended Citation
GB/T 7714
Ni, Chengsheng,Zhang, Yang,Huang, Xiubinget al. Effect of anode calcination on the performance and redox stability of low-temperature solid oxide fuel cells prepared via impregnation[J]. INTERNATIONAL JOURNAL OF HYDROGEN ENERGY,2017.
APA Ni, Chengsheng, Zhang, Yang, Huang, Xiubing, Zou, Jing, Zhang, Guan, & Ni, Jiupai. (2017). Effect of anode calcination on the performance and redox stability of low-temperature solid oxide fuel cells prepared via impregnation. INTERNATIONAL JOURNAL OF HYDROGEN ENERGY.
MLA Ni, Chengsheng,et al."Effect of anode calcination on the performance and redox stability of low-temperature solid oxide fuel cells prepared via impregnation".INTERNATIONAL JOURNAL OF HYDROGEN ENERGY (2017).
Files in This Item:
There are no files associated with this item.
Related Services
Usage statistics
Google Scholar
Similar articles in Google Scholar
[Ni, Chengsheng]'s Articles
[Zhang, Yang]'s Articles
[Huang, Xiubing]'s Articles
Baidu academic
Similar articles in Baidu academic
[Ni, Chengsheng]'s Articles
[Zhang, Yang]'s Articles
[Huang, Xiubing]'s Articles
Bing Scholar
Similar articles in Bing Scholar
[Ni, Chengsheng]'s Articles
[Zhang, Yang]'s Articles
[Huang, Xiubing]'s Articles
Terms of Use
No data!
Social Bookmark/Share
All comments (0)
No comment.

Items in the repository are protected by copyright, with all rights reserved, unless otherwise indicated.