Abstract
A high-throughput computational framework to identify novel multinary perovskite redox mediators is presented, and this framework is applied to discover the Gd-containing perovskite oxide compositions Gd2BB′O6, GdA′B2O6, and GdA′BB′O6 that split water. The computational scheme uses a sequence of empirical approaches to evaluate the stabilities, electronic properties, and oxygen vacancy thermodynamics of these materials, including contributions to the enthalpies and entropies of reduction, ΔHTR and ΔSTR. This scheme uses the machine-learned descriptor τ to identify compositions that are likely stable as perovskites, the bond valence method to estimate the magnitude and phase of BO6 octahedral tilting and provide accurate initial estimates of perovskite geometries, and density functional theory including magnetic- and defect-sampling to predict STCH-relevant properties. Eighty-three promising STCH candidate perovskite oxides down-selected from 4392 Gd-containing compositions are reported, three of which are referred to experimental collaborators for characterization and exhibit STCH activity. The results demonstrate that the high-throughput computational scheme described herein—which is used to evaluate Gd-containing compositions but can be applied to any multinary perovskite oxide compositional space(s) of interest—accelerates the discovery of novel STCH active redox mediators with reasonable computational expense.
| Original language | English |
|---|---|
| Article number | 2200201 |
| Journal | Advanced Functional Materials |
| Volume | 32 |
| Issue number | 25 |
| DOIs | |
| State | Published - Jun 17 2022 |
Funding
Z.B. and R.M. contributed equally to this work. The authors would like to thank their experimental collaborators, A. H. McDaniel, A. W. Weimer, E. N. Coker, J. T. Tran, J. E. Park, A. Ambrosini, J. A. Trindell, and M. A. Rodriguez for synthesizing and characterizing the candidate materials. The authors also thank S.L. Millican for helpful discussions related to candidate materials selection. Z.B. generated the computational data, workflow scheme, STCH candidate materials plots, and wrote the manuscript. R.M. created the MP effective mass plot, substitution matrix plot, and wrote the manuscript. C.M. supervised the project and calculations and edited the manuscript. This work was supported by the U.S. Department of Energy (DOE), Office of Energy Efficiency and Renewable Energy (EERE), Hydrogen and Fuel Cell Technologies Office (HFTO), and specifically the HydroGEN Advanced Water Splitting Materials Consortium, established as part of the Energy Materials Network under this same office (Award No. DE‐EE0008088). C.M., Z.B., and R.M. also acknowledge support from the National Science Foundation, Award Nos. NSF CHEM‐1800592 and CBET‐2016225. The views expressed in this article do not necessarily represent the views of the U.S. Department of Energy or the U.S. Government. R.M. would also like to acknowledge support from the University of Colorado‐Boulder's Graduate Assistance in Areas of National Need, GAANN, Materials for Energy Conversion and Sustainability grant, Award No. P200A180012.
Keywords
- concentrated solar energy
- density functional theory
- hydrogen
- perovskite
- thermochemical water splitting