[1] LAN R, IRVINE J T S, TAO S. Ammonia and related chemicals as potential indirect hydrogen storage materials. International Journal of Hydrogen Energy, 1482(2012).

[2] SCHUTH F, PALKOVITS R, SCHLOGL R et al. Ammonia as a possible element in an energy infrastructure: catalysts for ammonia decomposition. Energy & Environmental Science, 6278(2012).

[3] WAN Z, TAO Y, SHAO J et al. Ammonia as an effective hydrogen carrier and a clean fuel for solid oxide fuel cells. Energy Conversion and Management, 113729(2021).

[5] MAEDA A, HU Z, KUNIMORI K et al. Effect of high- temperature reduction on ammonia decomposition over niobia- supported and niobia-promoted rhodium catalysts. Catalysis Letters, 155(1988).

[6] JU X, LIU L, YU P et al. Mesoporous Ru/MgO prepared by a deposition-precipitation method as highly active catalyst for producing COx-free hydrogen from ammonia decomposition. Applied Catalysis B: Environmental, 167(2017).

[8] PARKER L A, CARTER J H, DUMMER N F et al. Ammonia decomposition enhancement by Cs-promoted Fe/Al2O3 catalysts. Catalysis Letters, 3369(2020).

[9] MALEKI H, BERTOLA V. Co-Ce-Al-O mesoporous catalysts for hydrogen generation via ammonia decomposition. International Journal of Hydrogen Energy, 267(2024).

[10] XU J, YAN H, JIN Z et al. Facile synthesis of stable MO2N nanobelts with high catalytic activity for ammonia decomposition. Chinese Journal of Chemistry, 364(2019).

[11] LI L, WU J, SHAO J et al. Impacts of SiO2 shell structure of Ni@SiO2 nanocatalysts on their performance for catalytic decomposition of ammonia. Catalysis Letters, 141(2016).

[12] SIMONSEN S B, CHAKRABORTY D, CHORKENDORFF I et al. Alloyed Ni-Fe nanoparticles as catalysts for NH3 decomposition. Applied Catalysis A: General, 22(2012).

[13] ZANMAN S F, JOLAOSO L A, PODILA S et al. Ammonia decomposition over citric acid chelated γ-Mo2N and Ni2Mo3N catalysts. International Journal of Hydrogen Energy, 17252(2018).

[14] HE H, JIANG H, YANG F et al. Bimetallic NixCo10-x/CeO2 as highly active catalysts to enhance mid-temperature ammonia decomposition: kinetics and synergies. International Journal of Hydrogen Energy, 5030(2023).

[15] PODILA S, DRISS H, ZAMAN S F et al. MgFe and Mg-Co-Fe mixed oxides derived from hydrotalcites: highly efficient catalysts for COx free hydrogen production from NH3. International Journal of Hydrogen Energy, 873(2020).

[16] PANSARE S S, TORRES W, GOODWIN J G. Ammonia decomposition on tungsten carbide. Catalysis Communications, 649(2007).

[17] CHOI J G. Ammonia decomposition over vanadium carbide catalysts. Journal of Catalysis, 104(1999).

[18] OTREMBA T, FRENZEL N, LERCH M et al. Kinetic studies on ammonia decomposition over zirconium oxynitride. Applied Catalysis A: General, 103(2011).

[19] LE T A, DO Q C, KIM Y et al. A review on the recent developments of ruthenium and nickel catalysts for COx-free H2 generation by ammonia decomposition. Korean Journal of Chemical Engineering, 1087(2021).

[20] TAKEHIRA K. Recent development of layered double hydroxide- derived catalysts—rehydration, reconstitution, and supporting, aiming at commercial application. Applied Clay Science, 112(2017).

[21] TAKEHIRA K. Autothermal reforming of CH4 over supported Ni catalysts prepared from Mg-Al hydrotalcite-like anionic clay. Journal of Catalysis, 43(2004).

[22] SERRANOL A, RODRIGUEZ L, MUNOZ G et al. Biogas reforming on La-promoted NiMgAl catalysts derived from hydrotalcite-like precursors. Journal of Power Sources, 4404(2011).

[23] BETCHAKU M, NAKAGAWA Y, TAMURA M et al. Combination of hydrotalcite-like-compound-derived Ni-Fe/Mg/Al and ceria- supported Rh catalysts for fuel reforming in exhaust gas recirculation system of gasoline engine. Fuel Processing Technology, 107061(2022).

[24] YU X P, CHU W, WANG N et al. Hydrogen production by ethanol steam reforming on NiCuMgAl catalysts derived from hydrotalcite-like precursors. Catalysis Letters, 1228(2011).

[25] DENG L, LIN H, LIU X et al. Nickel nanoparticles derived from the direct thermal reduction of Ni-containing Ca-Al layered double hydroxides for hydrogen generation via ammonia decomposition. International Journal of Hydrogen Energy, 38351(2021).

[26] SATO K, ABE N, KAWAGOE T et al. Supported Ni catalysts prepared from hydrotalcite-like compounds for the production of hydrogen by ammonia decomposition. International Journal of Hydrogen Energy, 6610(2017).

[27] SU Q, GU L, YAO Y et al. Layered double hydroxides derived Nix(MgyAlzOn) catalysts: enhanced ammonia decomposition by hydrogen spillover effect. Applied Catalysis B: Environmental, 451(2017).

[28] OLSBYE U, AKPORIAYE D, RYTTER E et al. On the stability of mixed M2+/M3+ oxides. Applied Catalysis A: General, 39(2002).

[29] OKURA K, MIYAZAKI K, MUROYAMA H et al. Ammonia decomposition over Ni catalysts supported on perovskite-type oxides for the on-site generation of hydrogen. RSC Advances, 32102(2018).

[30] MUROYAMA H, SABURI C, MATSUI T et al. Ammonia decomposition over Ni/La2O3 catalyst for on-site generation of hydrogen. Applied Catalysis A: General, 119(2012).

[31] [31] LIX, JIW, ZHAOJ, et al.Ammonia decomposition over Ru and Ni catalysts supported on fumed SiO2, MCM-41, and SBA-15. Journal of Catalysis, 2005, 236(2):181.

[32] ZHENG W, ZHANG J, GE Q et al. Effects of CeO2 addition on Ni/Al2O3 catalysts for the reaction of ammonia decomposition to hydrogen. Applied Catalysis B: Environmental, 98(2008).

[33] WU K, CAO C F, ZHOU C et al. Engineering of Ce3+-O-Ni structures enriched with oxygen vacancies via Zr doping for effective generation of hydrogen from ammonia. Chemical Engineering Science, 116818(2021).

[34] LIU H, ZHANG Y, LIU S et al. Ni-CeO2 nanocomposite with enhanced metal-support interaction for effective ammonia decomposition to hydrogen. Chemical Engineering Journal, 145371(2023).