High-throughput search for magnetic and topological order in transition metal oxides

Abstract: The discovery of intrinsic magnetic topological order in MnBi2Te4 has invigorated the search for materials with coexisting magnetic and topological phases. These multiorder quantum materials are expected to exhibit new topological phases that can be tuned with magnetic fields, but the search for such materials is stymied by difficulties in predicting magnetic structure and stability. Here, we compute more than 27,000 unique magnetic orderings for more than 3000 transition metal oxides in the Materials Project … Show more

“…Two of the five magnetic transitions of the n = 6 member overlap with two of the transitions in the n = 4 member, with the remaining three transitions overlapping with the transitions found in the n = 5 member, most likely due to their related local environments. − The n = ∞ member, CeCoGe 3 , is a Kondo antiferromagnet ( T K ∼ 100 K) with three magnetic transitions at T = 21 K, T = 12 K, and T = 8 K that resemble the anisotropy of the other n members. The presence of CeCoGe 3 in this series is particularly exciting, as the noncentrosymmetric superconductor has recently been theoretically predicted to be topologically nontrivial. − …”

Investigating the A_n+1B_nX_3n+1 Homologous Series: A New Platform for Studying Magnetic Praseodymium Based Intermetallics

“…Two of the five magnetic transitions of the n = 6 member overlap with two of the transitions in the n = 4 member, with the remaining three transitions overlapping with the transitions found in the n = 5 member, most likely due to their related local environments. − The n = ∞ member, CeCoGe 3 , is a Kondo antiferromagnet ( T K ∼ 100 K) with three magnetic transitions at T = 21 K, T = 12 K, and T = 8 K that resemble the anisotropy of the other n members. The presence of CeCoGe 3 in this series is particularly exciting, as the noncentrosymmetric superconductor has recently been theoretically predicted to be topologically nontrivial. − …”

Investigating the A_n+1B_nX_3n+1 Homologous Series: A New Platform for Studying Magnetic Praseodymium Based Intermetallics

“…Of course, this comes at a cost; these complex spaces must be mathematically modelled, and a significant number of the representative patterns must be available as examples for the ML system to learn from. ML classifiers can then be trained to predict material properties, as demonstrated for magnetic materials without requiring first-principles calculations [ 32 ].…”

Big data and machine learning for materials science

“…To address this issue, several groups have developed algorithms such as symmetry indicators and spin-orbit spillage that use materials chemistry and symmetry in combination with electronic structures to calculate its topological properties, opening the door to automated screening for new topological insulators and semimetals [66][67][68] . Based on these ideas, several searches through ICSD generated extensive lists of candidates corresponding to various types of topological materials [69][70][71][72][73] . Such developments make the field a fertile ground for the application of ML methods (for an example see Fig.…”

Artificial intelligence for search and discovery of quantum materials