(La1−xCax)MnO3−δ (x = 0, 0.2, 0.3, 0.4) Perovskites as Redox Catalysts in Chemical Looping Hydrogen Production Process: The Relation between Defect Chemistry and Redox Performance

Catalysts Pub Date : 2024-07-06 DOI:10.3390/catal14070431

Moschos Moschos, A. Evdou, Vassilios Zaspalis

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Abstract

The interaction between point defects in (La1−xCax)MnO3−δ (x = 0, 0.2, 0.3, 0.4) perovskites and their redox catalytic properties in a three-reactor chemical looping hydrogen production process is investigated. During the reduction step with CH4, the behavior of the materials is extrinsically determined and strongly depends on the Ca content. At small oxygen deficiencies, CH4 becomes oxidized to CO2. As the deficiency increases, partial oxidation to CO and H2 at a molar ratio of approximately 2 is favored. During the water-splitting step, the dependency on the Ca content is much weaker since it is intrinsically determined by the Mn2+→Mn3+ oxidation with simultaneous annihilation of oxygen vacancies that are not required to compensate for the extra negative charge of the Ca dopant. Hydrogen productivities in the order of 13 cm3 (STP) H2/g solid could be achieved during the water-splitting step at 1000 °C. The materials exhibited reproducible catalytic behavior during 10 cycles of the complete three-step process and were found to retain their perovskite structure.

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(La1-xCax)MnO3-δ（x = 0、0.2、0.3、0.4）过氧化物作为化学循环制氢过程中的氧化还原催化剂：缺陷化学与氧化还原性能之间的关系

研究了 (La1-xCax)MnO3-δ (x = 0, 0.2, 0.3, 0.4) 包晶石中的点缺陷与其在三反应器化学循环制氢过程中的氧化还原催化特性之间的相互作用。在与 CH4 的还原过程中，材料的行为是由外在决定的，并与 Ca 的含量密切相关。在缺氧较小时，CH4 会被氧化成 CO2。随着缺氧程度的增加，部分氧化成 CO 和 H2 的摩尔比约为 2。在分水步骤中，对 Ca 含量的依赖性要弱得多，因为它本质上是由 Mn2+→Mn3+ 氧化和氧空位同时湮灭决定的，而氧空位不需要补偿 Ca 掺杂剂的额外负电荷。在 1000 °C 的分水步骤中，氢气生产率可达到 13 cm3（STP）H2/g 固体的数量级。在完整的三步过程的 10 个循环中，这些材料表现出了可重复的催化行为，并保持了它们的包晶结构。

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