Selectivity in yttrium manganese oxide synthesis via local chemical potentials in hyperdimensional phase space

TL;DR

This paper introduces a general computational approach to design selective solid-state reactions by analyzing chemical potential landscapes, enabling targeted synthesis of metastable phases like Y2Mn2O7 using specific precursors.

Contribution

The study develops a novel method for predicting selective reactions in complex chemical spaces through chemical potential calculations, expanding the toolkit for materials synthesis.

Findings

Identified Na2CO3 as a unique precursor enabling Y2Mn2O7 synthesis.

Validated the mechanism with in situ crystallography.

Demonstrated pathway-dependent selectivity in solid-state reactions.

Abstract

In sharp contrast to molecular synthesis, materials synthesis is generally presumed to lack selectivity. The few known methods of designing selectivity in solid-state reactions have limited scope, such as topotactic reactions or strain stabilization. This contribution describes a general approach for searching large chemical spaces to identify selective reactions. This novel approach explains the ability of a nominally "innocent" Na$_2$CO$_3$ precursor to enable the metathesis synthesis of single-phase Y$_2$Mn$_2$O$_7$ -- an outcome that was previously only accomplished at extreme pressures and which cannot be achieved with closely related precursors of Li$_2$CO$_3$ and K$_2$CO$_3$. By calculating the required change in chemical potential across all possible reactant-product interfaces in an expanded chemical space including Y, Mn, O, alkali metals, and halogens, using thermodynamic parameters obtained from density functional theory calculations, we identify reactions that minimize the thermodynamic competition from intermediates. In this manner, only the Na-based intermediates minimize the distance in the hyperdimensional chemical potential space to Y$_2$Mn$_2$O$_7$, thus providing selective access to a phase which was previously thought to be metastable. Experimental evidence validating this mechanism for pathway-dependent selectivity is provided by intermediates identified from in situ synchrotron-based crystallographic analysis. This approach of calculating chemical potential distances in hyperdimensional compositional spaces provides a general method for designing selective solid-state syntheses that will be useful for gaining access to metastable phases and for identifying reaction pathways that can reduce the synthesis temperature, and cost, of technological materials.