[1] WANG Jianqiang, DAI Zhimin, XU Hongjie. Research status and prospect of comprehensive utilization of nuclear energy[J]. Bulletin of Chinese Academy of Sciences, 34, 460-468(2019).

[2] Milewski J, Kupecki J, Szczęśniak A et al. Hydrogen production in solid oxide electrolyzers coupled with nuclear reactors[J]. International Journal of Hydrogen Energy, 46, 3-35776(2021).

[3] Hauch A, Küngas R, Blennow P et al. Recent advances in solid oxide cell technology for electrolysis[J]. Science, 370, eaba6118(2020).

[4] HOU Quan, GUAN Chengzhi, XIAO Guoping et al. Effect of size on the electrolytic performance of solid oxide electrolysis cell[J]. Nuclear Techniques, 42, 030501(2019).

[5] Preininger M, Stoeckl B, Subotić V et al. Characterization and performance study of commercially available solid oxide cell stacks for an autonomous system[J]. Energy Conversion and Management, 203, 112215(2020).

[6] Preininger M, Stoeckl B, Subotić V et al. Performance of a ten-layer reversible Solid Oxide Cell stack (rSOC) under transient operation for autonomous application[J]. Applied Energy, 254, 113695(2019).

[7] Santhanam S, Heddrich M P, Riedel M et al. Theoretical and experimental study of Reversible Solid Oxide Cell (r-SOC) systems for energy storage[J]. Energy, 141, 202-214(2017).

[8] Irvine J T S, Neagu D, Verbraeken M C et al. Evolution of the electrochemical interface in high-temperature fuel cells and electrolysers[J]. Nature Energy, 1, 15014(2016).

[9] Guan C Z, Zhou J, Bao H L et al. Study of the relationship between the local geometric structure and the stability of La0.6Sr0.4MnO3-δ and La0.6Sr0.4FeO3-δ electrodes[J]. Nuclear Science and Techniques, 30, 21(2019).

[10] Chasta G, Himanshu, Dhaka M S. A review on materials, advantages, and challenges in thin film based solid oxide fuel cells[J]. International Journal of Energy Research, 46, 1-14658(2022).

[11] Tucker M C. Progress in metal-supported solid oxide electrolysis cells: a review[J]. International Journal of Hydrogen Energy, 45, 2-24218(2020).

[12] Ghiara G, Piccardo P, Bongiorno V et al. Characterization of metallic interconnects extracted from Solid Oxide Fuel Cell stacks operated up to 20, 000 h in real life conditions: the fuel side[J]. International Journal of Hydrogen Energy, 46, 2-23827(2021).

[13] Peters R, Frank M, Tiedemann W et al. Long-term experience with a 5/15kW-class reversible solid oxide cell system[J]. Journal of the Electrochemical Society, 168, 014508(2021).

[14] Xue Y J, Guan W B, He C R et al. Anode supported planar solid oxide fuel cells with the large size of 30 cm×30 cm via tape-casting and co-sintering technique[J]. International Journal of Hydrogen Energy, 41, 1871-1876(2016).

[15] Lin J, Chen L, Liu T et al. The beneficial effects of straight open large pores in the support on steam electrolysis performance of electrode-supported solid oxide electrolysis cell[J]. Journal of Power Sources, 374, 175-180(2018).

[16] Hedayat N, Panthi D, Du Y H. Fabrication of tubular solid oxide fuel cells by solvent-assisted lamination and co-firing a rolled multilayer tape cast[J]. International Journal of Applied Ceramic Technology, 15, 307-314(2018).

[17] Niaz K, Bahadar H, Maqbool F et al. A review of environmental and occupational exposure to xylene and its health concerns[J]. EXCLI Journal, 14, 1167-1186(2015).

[18] Chen X, Zhang H L, Li Y Y et al. Fabrication and performance of anode-supported proton conducting solid oxide fuel cells based on BaZr0.1Ce0.7Y0.1Yb0.1O3-δ electrolyte by multi-layer aqueous-based co-tape casting[J]. Journal of Power Sources, 506, 229922(2021).

[19] Zhou J, Liu Q L, Zhang L et al. A study of short stack with large area solid oxide fuel cells by aqueous tape casting[J]. International Journal of Hydrogen Energy, 41, 1-18206(2016).

[20] Wang H R, Lei Z, Zhang H et al. Al2O3 toughening ScSZ electrolyte fabricated by water-based tape casting technique for solid oxide fuel cells[J]. Journal of Electrochemical Energy Conversion and Storage, 19, 011007(2022).

[21] LUO Linghong, LIU Shaoshuai, CHENG Liang. Water-based casting technology and its application in solid oxide fuel cells[J]. Journal of Ceramics, 40, 139-147(2019).

[22] Goulart C, de Souza D. Critical analysis of aqueous tape casting, sintering, and characterization of planar Yttria-Stabilized Zirconia electrolytes for SOFC[J]. International Journal of Applied Ceramic Technology, 14, 413-423(2017).

[23] Liu C, Zhang L, Zheng Y F et al. Study of a fuel electrode-supported solid oxide electrolysis cell prepared by aqueous Co-tape casting[J]. International Journal of Electrochemical Science, 14, 1-11579(2019).

[24] Zhou J, Ma Z, Zhang L et al. Study of CO2 and H2O direct co-electrolysis in an electrolyte-supported solid oxide electrolysis cell by aqueous tape casting technique[J]. International Journal of Hydrogen Energy, 44, 2-28946(2019).

[25] CHENG Liang, LUO Linghong, SHI Jijun et al. Ni/YSZ anode impregnated La2O3 on anti-carbon deposition of SOFC cell[J]. Journal of Inorganic Materials, 32, 241-246(2017).

[26] Verbraeken M C, Sudireddy B R, Vasechko V et al. Scaling up aqueous processing of A-site deficient strontium titanate for SOFC anode supports[J]. Journal of the European Ceramic Society, 38, 1663-1672(2018).

[27] Cui T H, Li H Y, Lyu Z W et al. Identification of electrode process in large-size solid oxide fuel cell[J]. Acta Physico-Chimica Sinica, 38, 2011009(2020).