Charting new regions of Cobalt's chemical space with maximally large magnetic anisotropy: A computational high-throughput study

arXiv - PHYS - Chemical Physics Pub Date : 2024-09-06 DOI:arxiv-2409.04418

Lorenzo A. Mariano, Vu Ha Anh Nguyen, Valerio Briganti, Alessandro Lunghi

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Abstract

Magnetic anisotropy slows down magnetic relaxation and plays a prominent role in the design of permanent magnets. Coordination compounds of Co(II) in particular exhibit large magnetic anisotropy in the presence of low-coordination environments and have been used as single-molecule magnet prototypes. However, only a limited sampling of Cobalt's vast chemical space has been performed, potentially obscuring alternative chemical routes toward large magnetic anisotropy. Here we perform a computational high-throughput exploration of Co(II)'s chemical space in search of new single-molecule magnets. We automatically assemble a diverse set of about 15000 novel complexes of Co(II) and fully characterize them with multi-reference ab initio methods. More than 100 compounds exhibit magnetic anisotropy comparable to or larger than leading known compounds. The analysis of these results shows that compounds with record-breaking magnetic anisotropy can also be achieved with coordination four or higher, going beyond the established paradigm of two-coordinated linear complexes.

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描绘具有最大磁各向异性的钴化学空间新区域：高通量计算研究

磁各向异性会减缓磁弛豫，在永磁体的设计中发挥着重要作用。特别是 Co（II）的配位化合物，在存在流配位环境时会表现出很大的磁各向异性，并已被用作单分子磁体原型。然而，人们只对钴的广阔化学空间进行了有限的取样，这可能掩盖了实现大磁各向异性的其他化学途径。在此，我们对钴（II）的化学空间进行了计算高通量探索，以寻找新的单分子磁体。我们自动组装了大约 15000 个新型 Co（II）配合物，并使用多参考ab initio 方法对它们进行了全面表征。对这些结果的分析表明，具有破纪录磁各向异性的化合物也可以通过四配位或更高配位实现，超越了双配位线性配合物的既定范例。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Chemical Physics

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