[1] SHI H, TANG J, YU W et al. Advances in power generation from ammonia via electrocatalytic oxidation in direct ammonia fuel cells[J]. Chemical Engineering Journal(2024).

[2] SHAO Z, NI M. Fuel cells: materials needs and advances[J]. MRS Bulletin(2024).

[4] SHI H G, LI Q J, TAN W Y et al. Solid oxide fuel cells in combination with biomass gasification for electric power generation[J]. Chinese Journal of Chemical Engineering(2020).

[5] LEE H S, LEE H M, PARK J Y et al. Degradation behavior of Ni-YSZ anode-supported solid oxide fuel cell (SOFC) as a function of H₂S concentration[J]. International Journal of Hydrogen Energy(2018).

[6] HANIF M A, IBRAHIM N, JALIL A A. Sulfur dioxide removal: an overview of regenerative flue gas desulfurization and factors affecting desulfurization capacity and sorbent regeneration[J]. Environmental Science and Pollution Research(2020).

[7] XIA C G, LI Z Q, WANG S Y et al. Recent progress on efficient perovskite ceramic anodes for high-performing solid oxide fuel cells[J]. International Journal of Hydrogen Energy(2024).

[8] LIU X, QI H, WEN H et al. Enhancing electrochemical performance and sulfur tolerance of Ni-based anodes coated by SrTi_0.5Mo_0.2Ni_0.3-xO_3-δ perovskite with nano-nickel for solid oxide fuel cells[J]. Fuel(2023).

[9] JAISWAL S, MONDAL R, KUSHWAHA V et al. Tuning of redox energy of transition-metal ions through the utilization of interlayer potentials in layered perovskites: development of a titanium-based superior HER catalyst in an acidic medium[J]. ACS Applied Energy Materials(2023).

[10] SONG Y, WANG W, GE L et al. Rational design of a water-storable hierarchical architecture decorated with amorphous barium oxide and nickel nanoparticles as a solid oxide fuel cell anode with excellent sulfur tolerance[J]. Advanced Science(2017).

[11] KIM J H, CHERN Z Y, YOO S et al. Unraveling the mechanism of water-mediated sulfur tolerance via operando surface-enhanced raman spectroscopy[J]. ACS Applied Materials & Interfaces(2019).

[12] ZHENG H, ZHANG Y, WANG Y et al. Perovskites with enriched oxygen vacancies as a family of electrocatalysts for efficient nitrate reduction to ammonia[J]. Small(2022).

[13] YANG G, SU C, RAN R et al. Advanced symmetric solid oxide fuel cell with an infiltrated K₂NiF₄-type La₂NiO₄ electrode[J]. Energy & Fuels(2013).

[14] SANDOVAL M V, CARDENAS C, CAPOEN E et al. Performance of La_0.5Sr_1.5MnO_4±δ Ruddlesden-Popper manganite as electrode material for symmetrical solid oxide fuel cells. Part B.The hydrogen oxidation reaction[J]. Electrochimica Acta(2020).

[15] ZHANG X, TONG Y, LIU T et al. Robust Ruddlesden-Popper phase Sr₃Fe_1.3Mo_0.5Ni_0.2O_7-δ decorated with in-situ exsolved Ni nanoparticles as an efficient anode for hydrocarbon fueled solid oxide fuel cells[J]. SusMat(2022).

[16] RICCIARDULLI A G, YANG S, SMET J H et al. Emerging perovskite monolayers[J]. Nature Materials(2021).

[17] XU X, PAN Y, ZHONG Y et al. Ruddlesden-Popper perovskites in electrocatalysis[J]. Materials Horizons(2020).

[19] ZHENG X, LI B, SHEN L et al. Oxygen vacancies engineering of Fe doped LaCoO₃ perovskite catalysts for efficient H₂S selective oxidation[J]. Applied Catalysis B: Environmental(2023).

[20] SANDOVAL M V, PIROVANO C, CAPOEN E et al. In-depth study of the Ruddlesden-Popper La_xSr_2-xMnO_4±δ family as possible electrode materials for symmetrical SOFC[J]. International Journal of Hydrogen Energy(2017).

[21] KIM K J, RATH M K, KWAK H H et al. A highly active and redox-stable SrGdNi_0.2Mn_0.8O_4±δ anode with in situ exsolution of nanocatalysts[J]. ACS Catalysis(2019).

[22] ZHAO Y, ZHU Y, ZHU J et al. Atomic-resolution investigation of structural transformation caused by oxygen vacancy in La_0.9Sr_0.1TiO_3+δ titanate layer perovskite ceramics[J]. Journal of Materials Science & Technology(2022).

[24] WU M, YU H, NI J et al. Coke-resistant ferrite anode decorated with in-situ exsolved ceria for carbonaceous fuel oxidation[J]. Journal of Power Sources(2022).

[25] JIANG H, LIANG Z, QIU H et al. A high-performance and durable direct-ammonia symmetrical solid oxide fuel cell with nano La_0.6Sr_0.4Fe_0.7Ni_0.2Mo_0.1O_3-δ-decorated doped ceria electrode[J]. Nanomaterials(2024).

[26] ZHANG L, MENG M, WANG X et al. A series of copper-free ternary oxide catalysts ZnAlCe_x used for hydrogen production via dimethyl ether steam reforming[J]. Journal of Power Sources(2014).

[27] OLIVEIRA DE, MENEGUIN J G, PEREIRA M V et al. H₂S adsorption on NaY zeolite[J]. Microporous and Mesoporous Materials(2019).

[28] PAN J L, MA G J, SONG L M et al. High stability/catalytic activity Co-based perovskite as SOFC anode: in-situ preparation by fuel reducing method[J]. Journal of Inorganic Materials(2024).

[29] MABAYOJE O, SEREDYCH M, BANDOSZ T J. Enhanced adsorption of hydrogen sulfide on mixed zinc/cobalt hydroxides: effect of morphology and an increased number of surface hydroxyl groups[J]. Journal of Colloid and Interface Science(2013).

[30] BINEESH K V, KIM D K, KIM M I L et al. Selective catalytic oxidation of H₂S over V₂O₅ supported on TiO₂-pillared clay catalysts in the presence of water and ammonia[J]. Applied Clay Science(2011).

[31] ZHAO J, XU X, ZHOU W et al. Proton-conducting La-doped ceria-based internal reforming layer for direct methane solid oxide fuel cells[J]. ACS Applied Materials & Interfaces(2017).

[32] CRAVANZOLA S, CESANO F, GAZIANO F et al. Sulfur-doped TiO₂: structure and surface properties[J]. Catalysts(2017).

[33] GUO Z, ZHANG Z, CAO X et al. Fe-Ti bimetal oxide adsorbent for removing low concentration H₂S at room temperature[J]. Environmental Technology(2021).

[35] XUE K, CAI C K, XIE M Y et al. Preparation and electrochemical performance of Pr_1+xBa_1-xFe₂O_5+δ cathode materials for solid oxide fuel cells[J]. Journal of Inorganic Materials.