Garnets, known since the early stages of human civilization, have found important applications in modern technologies including magnetorestriction, spintronics, lithium batteries, etc. The overwhelming majority of experimentally known garnets are oxides, while explorations (experimental or theoretical) for the rest of the chemical space have been limited in scope. A key issue is that the garnet structure has a large primitive unit cell, requiring an enormous amount of computational resources. To perform a comprehensive search of the complete chemical space for new garnets,we combine recent progress in graph neural networks with high-throughput calculations. We apply the machine learning model to identify the potential (meta-)stable garnet systems before systematic density-functional calculations to validate the predictions. In this way, we discover more than 600 ternary garnets with distances to the convex hull below 100~meV/atom with a variety of physical and chemical properties. This includes sulfide, nitride and halide garnets. For these, we analyze the electronic structure and discuss the connection between the value of the electronic band gap and charge balance.
翻译:自人类文明早期阶段以来就一直已知的加内网在现代技术中找到了重要的应用,包括磁场限制、脊柱、锂电池等。绝大多数实验性已知的加内网都是氧化物,而化学空间其余部分的勘探(实验性或理论性)范围有限。一个关键问题是,加内网结构有一个庞大的原始单元细胞,需要大量的计算资源。为了对新的加内网的完整化学空间进行全面的搜索,我们把图形神经网络最近的进展与高通量计算结合起来。我们应用机器学习模型在系统计算密度功能之前查明(分子-)可分布式加内系统的潜力,以验证预测。这样,我们发现了600多顶长的加内网,距离孔壳不到100~米V/原子,有各种物理和化学特性。其中包括硫化物、硝化物和卤化物加内网。对于这些,我们分析电子结构,并讨论电子波位平衡值与电子波段平衡之间的关联。