利用假设驱动的主动学习在过氧化物中实现结构模式耦合

Ayana Ghosh, Palanichamy Gayathri, Monirul Shaikh, Saurabh Ghosh
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摘要

找到能量最小的基态结构对于设计任何材料都至关重要。在具有 Pnma 对称性的 ABO3 型包晶氧化物中,最低能量相是由两个主要阶次参数(如旋转和倾斜)之间固有的三线耦合以及 A 位阳离子的反铁电位移驱动的,这种耦合是通过混合不当铁电机制建立的。传统上,确定驱动相变的相关模式耦合需要进行第一性原理计算,这既耗时又昂贵。这需要采用直观的迭代和试验方法:(a)添加两个或多个模式矢量,(b)评估哪种组合会导致基态能量。在本研究中,我们展示了假设驱动的主动学习框架如何在朗道自由能展开中,以最少的模式振幅信息,为一系列具有 A 位层状、柱状和岩盐有序的双过氧化物确定合适的模式耦合。这一方案有望普遍适用于理解由功能背后的各种结构模式耦合衍生出的原子机制,例如极化、磁化和金属-绝缘体转变。
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Structural mode coupling in perovskite oxides using hypothesis-driven active learning
Finding the ground-state structure with minimum energy is paramount to designing any material. In ABO3-type perovskite oxides with Pnma symmetry, the lowest energy phase is driven by an inherent trilinear coupling between the two primary order parameters such as rotation and tilt with antiferroelectric displacement of the A-site cations as established via hybrid improper ferroelectric mechanism. Conventionally, finding the relevant mode coupling driving phase transition requires performing first-principles computations which is computationally time-consuming as well as expensive. It involves following an intuitive iterative hit and trial method of (a) adding two or multiple mode vectors, (b) evaluating which combination would lead to the ground-state energy. In this study, we show how a hypothesis-driven active learning framework can identify suitable mode couplings within the Landau free energy expansion with minimal information on amplitudes of modes for a series of double perovskite oxides with A-site layered, columnar and rocksalt ordering. This scheme is expected to be applicable universally for understanding atomistic mechanisms derived from various structural mode couplings behind functionalities, for e.g., polarization, magnetization and metal-insulator transitions.
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