Probing the origin of the giant magnetic anisotropy in trigonal bipyramidal Ni(ii) under high pressure

Understanding and controlling magnetic anisotropy at the level of a single metal ion is vital if the miniaturisation of data storage is to continue to evolve into transformative technologies. Magnetic anisotropy is essential for a molecule-based magnetic memory as it pins the magnetic moment of a me...

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Bibliographic Details
Published in:Chemical science (Cambridge) 2018-02, Vol.9 (6), p.1551-1559
Main Authors: Craig, Gavin A, Sarkar, Arup, Woodall, Christopher H, Hay, Moya A, Marriott, Katie E R, Kamenev, Konstantin V, Moggach, Stephen A, Brechin, Euan K, Parsons, Simon, Rajaraman, Gopalan, Murrie, Mark
Format: Article
Language:English
Subjects:
Anisotropy
Chemistry
Coordination compounds
Data storage
Hydrostatic pressure
Ligands
Magnetic anisotropy
Magnetic measurement
Magnetic moments
Magnetic properties
Metal ions
Molecular structure
Nickel
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Summary:Understanding and controlling magnetic anisotropy at the level of a single metal ion is vital if the miniaturisation of data storage is to continue to evolve into transformative technologies. Magnetic anisotropy is essential for a molecule-based magnetic memory as it pins the magnetic moment of a metal ion along the easy axis. Devices will require deposition of magnetic molecules on surfaces, where changes in molecular structure can significantly alter magnetic properties. Furthermore, if we are to use coordination complexes with high magnetic anisotropy as building blocks for larger systems we need to know how magnetic anisotropy is affected by structural distortions. Here we study a trigonal bipyramidal nickel(ii) complex where a giant magnetic anisotropy of several hundred wavenumbers can be engineered. By using high pressure, we show how the magnetic anisotropy is strongly influenced by small structural distortions. Using a combination of high pressure X-ray diffraction, methods and high pressure magnetic measurements, we find that hydrostatic pressure lowers both the trigonal symmetry and axial anisotropy, while increasing the rhombic anisotropy. The ligand-metal-ligand angles in the equatorial plane are found to play a crucial role in tuning the energy separation between the d and d orbitals, which is the determining factor that controls the magnitude of the axial anisotropy. These results demonstrate that the combination of high pressure techniques with studies is a powerful tool that gives a unique insight into the design of systems that show giant magnetic anisotropy.
ISSN:2041-6520
2041-6539
DOI:10.1039/c7sc04460g