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Researchers Discover New Class of Magnetism, Dubbed “Altermagnetism”

Patches of different colors twist together under magnetic forces, shown by arrows.
Mapping an altermagnetic vortex pair in MnTe. The six colours, with arrows overlayed, show the direction of the altermagnetic ordering within the material. The size of the region shown is 1μm2. Credit: Oliver Amin, University of Nottingham
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A new class of magnetism called altermagnetism has been imaged for the first time in a new study. The findings could lead to the development of new magnetic memory devices with the potential to increase operation speeds of up to a thousand times.


Altermagnetism is a distinct form of magnetic order where the tiny constituent magnetic building blocks align antiparallel to their neighbours but the structure hosting each one is rotated compared to its neighbours.


Scientists from the University of Nottingham’s School of Physics and Astonomy have shown that this new third class of magnetism exists and can be controlled in microscopic devices. The findings have been published today in Nature.

Altermagnets consist of magnetic moments that point antiparallel to their neighbours. However, each part of the crystal hosting these tiny moments is rotated with respect to its neighbours. This is like antiferromagnetism with a twist! But this subtle difference has huge ramifications.
Professor Peter Wadley, School of Physics and Astronomy

 

Magnetic materials are used in the majority of long term computer memory and the latest generation of microelectronic devices. This is not only a massive and vital industry but also a significant source of global carbon emissions. Replacing the key components with altermagnetic materials would lead to huge increases in speed and efficiency while having the potential to massively reduce our dependency on rare and toxic heavy elements needed for conventional ferromagnetic technology.

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Altermagnets combine the favourable properties of ferromagnets and antiferromagnets into a single material. They have the potential to lead to a thousand fold increase in speed of microelectronic components and digital memory while being more robust and m energy efficient.

Our experimental work has provided a bridge between theoretical concepts and real-life realisation, which hopefully illuminates a path to developing altermagnetic materials for practical applications.
Oliver Amin, Senior Research Fellow, School of Physics and Astronomy

The new experimental study was carried out at the MAX IV international facility in Sweden. The facility, which looks like a giant metal doughnut, is an electron accelerator, called a synchrotron, that produces x-rays.


X-rays are shone onto the magnetic material and the electrons given off from the surface are detected using a special microscope. This allows an image to be produced of the magnetism in the material with resolution of small features down to the nanoscale.


PhD student, Alfred Dal Din, has been exploring altermagnets for the last two years. This is yet another breakthrough that he has seen during his project. He comments: 'To be amongst the first to see the effect and properties of this promising new class of magnetic materials during my PhD has been an immensely rewarding and challenging privilege.'


Reference: Amin OJ, Dal Din A, Golias E, et al. Nanoscale imaging and control of altermagnetism in MnTe. Nature. 2024;636(8042):348-353. doi: 10.1038/s41586-024-08234-x


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