Heuristic Engineering of Magnetic Mn4Ta2O9 Phases from High-Pressure and High-Temperature Synthesis

Rational design and precise high-pressure and high-temperature (HPHT) synthesis of metastable oxides, such as polar magnets for desired functions, remain a long-standing challenge, which is largely dominated by thermodynamically controlled atomic-scale engineering of the local structure. Although cutting-edge research can reliably predict the synthetic pressure (P) for the target product, theoretical attempts to estimate the reaction temperature (T) remain elusive to date in HPHT synthesis, thus necessitating further strategies to confine the T and avoid costly trial-and-error. Here, Mn₄Ta₂O₉ (MTO) is adopted as a prototype to reveal the correlation between local crystal structure and formation conditions, namely, the synthetic P and T. Three high pressure polar polymorphs of MTO crystallized in Cc, R3, and R3c were synthesized at 5 to 8 GPa up to 1623 K from the ambient pressure P3̅c1 phase. All polymorphs exhibit the predominance of antiferromagnetic interactions from long to short-range ordering along the P3̅c1–Cc–R3–R3c evolution. Thermodynamic analyses interpret well the T-origin of the observed phase modification and are expected to guide the potential inverse design. These findings afford an approach to thermodynamically evaluate the possibility of phase modification at certain P and significantly confined T, and they are expected to accelerate the discoveries of related materials by state-of-the-art HPHT synthesis.