Exploring Topochemical Oxidation Reactions for Reversible Tuning of Thermal Conductivity in Perovskite Fe Oxides
Noa Varela‐Domínguez, Marcel S. Claro, Enrique Carbó‐Argibay, César Magén, F. Rivadulla
Abstract
High Resolution Image Download MS PowerPoint Slide We present a study on the reversibility of thermal conductivity in iron oxides through topochemical oxygen exchange between brownmillerite (BM) (Ca,Sr)FeO 2.5 and perovskite (PV) (Ca,Sr)FeO 3.0 . By using different oxidation methods, including gas phase (O 2 /O 3 ), liquid phase (NaOCl in H 2 O), and solid electrolyte (Y 2 O 3:ZrO 2 ), we demonstrate that the oxidation pathway has a critical influence on the reversibility of the ionic-exchange process. Cyclic oxidation and reduction using O 2 /O 3 or NaOCl lead to an important accumulation of structural defects, undermining the reversibility of thermal conductivity. In the case of wet oxidation, we demonstrate an inherent tendency of negative charge-transfer oxides toward amorphization and elucidate the origin of this effect. Conversely, the electrochemical injection of the O 2– ions via a Y 2 O 3:ZrO 2 solid electrolyte reduces structural damage significantly, enhancing both reversibility and durability. This study underscores the importance of selecting appropriate topochemical oxygen exchange methods to maintain structural integrity and optimize functional performance in oxide-based tunable devices.