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A Novel High‐Entropy Perovskite Electrolyte with Improved Proton Conductivity and Stability for Reversible Protonic Ceramic Electrochemical Cells

Seeun Oh, Dongyeon Kim, Ho Ryu, Kang Taek Lee

2023Advanced Functional Materials42 citationsDOIOpen Access PDF

Abstract

Abstract Reversible protonic ceramic electrochemical cells (R‐PCECs) are emerging as highly efficient energy conversion devices, operating below 650 °C. The primary challenge in advancing R‐PCECs lies in developing efficient and stable proton‐conducting electrolytes capable of withstanding the chemical instability caused by common contaminants like CO 2 and H 2 O. Herein, a novel high‐entropy perovskite oxide (HEPO) material is introduced, incorporating six equimolar B‐site cations (BaHf 1/6 Sn 1/6 Zr 1/6 Ce 1/6 Y 1/6 Yb 1/6 O 3‐δ , BHSZCYYb). The total conductivity of BHSZCYYb outperforms that of the examined HEPO electrolytes and other reported HEPO variants. Additionally, superior chemical stability of BHSZCYYb is observed when exposed to CO 2 . Utilizing the microwave‐assisted sintering method, an R‐PCEC with BHSZCYYb electrolyte is successfully fabricated. This cell exhibits a maximum power density of 1.151 W cm −2 (650 °C) in fuel cell mode and a current density of 2.326 A cm −2 at 1.3 V (650 °C) in electrolysis cell mode. These results represent the highest‐reported values for R‐PCECs employing HEPO electrolytes to date and provide valuable insights into the development and advancement of HEPOs, holding great promise for achieving high‐performance R‐PCECs.

Topics & Concepts

ElectrolyteMaterials scienceConductivityElectrochemistryPerovskite (structure)CeramicChemical engineeringOxideSinteringElectrolysisNanotechnologyElectrodePhysical chemistryChemistryComposite materialMetallurgyEngineeringAdvancements in Solid Oxide Fuel CellsThermal Expansion and Ionic ConductivityMagnetic and transport properties of perovskites and related materials