Methodological Approach to the High-Pressure Synthesis of Nonmagnetic Li₂B⁴⁺B′⁶⁺O₆ Oxides

Abstract: High-pressure solid-state synthesis advances boost discoveries of new materials and unusual phenomena but endures stringent recipe conditions, poor yield, and high cost. A methodological approach for accelerated and precisely high-pressure synthesis is therefore highly desired. Here, we take the exotic double-perovskite-related nonmagnetic Li2 B +4 B′+6O6 as an example to show the pipeline of data-mining, high-throughput calculations, experimental realization, and chemical interception of metastable phases. A … Show more

“…As shown in Table S2, the bond distance of Mn–O ranges from 2.050(13) to 2.390(11) Å and that of Mo–O from 1.859(9) to 1.988(18) Å, rendering strong anisotropy and large P s calculated to be 65.76 μC·cm –2 by the point charge model . Previous research demonstrates that, for polar-corundum-type derivatives, the polarization reversal barrier ( E barrier ) of the domain wall shows a strong correlation to the local bonding environment of A-site cations, as can be evaluated by normalized bond-valence sums (BVS). ,,− On this basis, the E barrier of Mn 2 MnMoO 6 is estimated to be about 232 meV (Figure b), which is between the values of Mn 2 FeMoO 6 , and Mn 2 MnWO 6 . The average ⟨Mn1–O⟩ bond length (2.170 (15) Å) in Mn 2 MnMoO 6 is comparable with those in Mn 2 MnWO 6 (2.00 Å) and Mn 2 FeMoO 6 (2.195 Å) .…”

“…“*” Represents an unknown impurity. (b) Comparison of E barrier between Mn 2 MnMoO 6 and other polar-corundum compounds. ,,− Reprinted with permission from ref . Copyright 2021 American Chemical Society.…”

High-Pressure Synthesis of Polar and Antiferromagnetic Mn₂MnMoO₆

“…As shown in Table S2, the bond distance of Mn–O ranges from 2.050(13) to 2.390(11) Å and that of Mo–O from 1.859(9) to 1.988(18) Å, rendering strong anisotropy and large P s calculated to be 65.76 μC·cm –2 by the point charge model . Previous research demonstrates that, for polar-corundum-type derivatives, the polarization reversal barrier ( E barrier ) of the domain wall shows a strong correlation to the local bonding environment of A-site cations, as can be evaluated by normalized bond-valence sums (BVS). ,,− On this basis, the E barrier of Mn 2 MnMoO 6 is estimated to be about 232 meV (Figure b), which is between the values of Mn 2 FeMoO 6 , and Mn 2 MnWO 6 . The average ⟨Mn1–O⟩ bond length (2.170 (15) Å) in Mn 2 MnMoO 6 is comparable with those in Mn 2 MnWO 6 (2.00 Å) and Mn 2 FeMoO 6 (2.195 Å) .…”

“…“*” Represents an unknown impurity. (b) Comparison of E barrier between Mn 2 MnMoO 6 and other polar-corundum compounds. ,,− Reprinted with permission from ref . Copyright 2021 American Chemical Society.…”

High-Pressure Synthesis of Polar and Antiferromagnetic Mn₂MnMoO₆

“…It possesses a very high ferrimagnetic Curie temperature T C of 580 K and a considerable magnetic moment of 5.0 μ B /fu. The charge and spin configuration is Cu 2+ (↑)­Fe 3+ (↑)­Os 5+ (↓), quite analogous to some other isostructural systems ,, and with also signs for the presence of orbital moments. , It is worth noting that CCFOO was synthesized under the high-pressure and high-temperature (HPHT) method, which is able to stabilize the metastable phase at ambient pressure. − …”

Comparative Study on the Magnetic and Transport Properties of B-Site Ordered and Disordered CaCu₃Fe₂Os₂O₁₂

“…Seven polymorphs are known for the exotic perovskiterelated A 2 BB′O 6 compounds, among which Li 2 BTeO 6 are more likely to crystalize in R3-OIL, Pnn2, R3-NTO, and P21/n structures. 37 Here, the E−V curves for the above four possible polymorphs were computed for LTTO using DFT, as shown in Figure 3b, where the α-phase (Pnn2) is the most stable one with the lowest internal energy at V 0 (ambient pressure), docking on the energy convex hull of the phase diagram (thermodynamically stable phase) 49 and can be synthesized by the conventional solid-state reaction at ambient pressure. 50 The energy of the β-phase (NTO-type R3) becomes lower than that of the α-phase above 6 GPa as has been experimentally validated in our previous work.…”

“…LTTO was found to transform from stable Pnn2 (α) to metastable Ni 3 TeO 6 (NTO)-type R3 (β) under high pressure (6 GPa) upon temperature quenching as predicted. 37 Given the similar chemical compositions and local structure between β-LTTO and Na 2 TiTeO 6 (NTTO), it is thus expected to obtain a metastable LTTO phase via the topotactic reaction. Here, we revisited the structure of NTTO and found out that NTTO adopts the ordered-ilmenite (OIL)-type R3 structure rather than the reported ilmenite (R3̅ ) symmetry.…”

Metastable γ-Li₂TiTeO₆: Negative Chemical Pressure Interception and Polymorph Tuning of SHG