Compositionally Complex Perovskite Oxides for Solar Thermochemical Water Splitting

TL;DR

This study introduces a new class of compositionally complex perovskite oxides that enhance solar thermochemical water splitting efficiency and stability through tailored redox properties and entropy stabilization.

Contribution

It explores a novel high-entropy perovskite oxide for STCH, demonstrating improved stability, tunable redox behavior, and a new computational approach for mechanism elucidation.

Findings

Maximum H2 yield of 395 μmol g-1 in 1 hour redox cycle

Stable over 50 cycles under harsh conditions

Optimal Co content balances thermodynamics and kinetics

Abstract

Solar thermochemical hydrogen generation (STCH) is a promising approach for eco-friendly H2 production, but conventional STCH redox compounds often suffer from thermodynamic and kinetic limitations with limited tunability. Expanding from the nascent high-entropy ceramics field, this study explores a new class of compositionally complex perovskite oxides (La0.8Sr0.2)(Mn(1-x)/3Fe(1-x)/3CoxAl(1-x)/3)O3 for STCH. In situ X-ray diffraction demonstrates the phase stability during redox cycling and in situ X-ray photoelectron spectroscopy shows preferential redox of Co. The extent of reduction increases, but the intrinsic kinetics decreases, with increased Co content. Consequently, (La0.8Sr0.2)(Mn0.2Fe0.2Co0.4Al0.2)O3-{\delta} achieves an optimal balance between the thermodynamics and kinetics properties. The combination of a moderate enthalpy of reduction, high entropy of reduction, and preferable surface oxygen exchange kinetics enables a maximum H2 yield of 395 +- 11 {\mu}mol g-1 in a short 1-hour redox duration. Entropy stabilization expectedly contributes to the structure stability during redox without phase transformation, which enables an exceptional STCH stability for >50 cycles under harsh interrupted conditions. The underlying redox mechanism is further elucidated by the density functional theory based parallel Monte Carlo computation, which represents a new computation paradigm first established here. This study suggests a new class of non-equimolar compositionally complex ceramics for STCH and chemical looping.