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11/09/2020 11:49

Antiferromagnets are suitable for dissipationless nanoelectronics, contrary to popular belief

Petra Giegerich Kommunikation und Presse
Johannes Gutenberg-Universität Mainz

    Young physicist at Mainz University discovers the Hall effect in an antiferromagnet, which – according to current theories – is impossible

    Sometimes combinations of different things produce effects that no one expects, such as when completely new properties appear that the two combined parts do not have on their own. Dr. Libor Šmejkal from Johannes Gutenberg University Mainz (JGU) found such an unexpected property: He combined antiferromagnetic substances with non-magnetic atoms and found that, contrary to the current doctrine, a Hall current occurs – which is not the case with either antiferromagnetic or non-magnetic substances individually.

    This could offer completely new potential for nanoelectronics. On the one hand, these material combinations occur very frequently in nature. Therefore, this discovery has the potential to revert the growing demand for rare heavy elements in conventional magneto-electronics and, instead, direct the research and applications towards abundant materials. Furthermore, the Hall current exhibits low dissipation of energy. This is particularly important in light of the fact that information technology is becoming the largest energy consumer in industries. Since the materials do not have a magnetic field to the outside and are thus magnetically invisible, they can be packed very tightly and allow a high degree of miniaturization of nanoelectronics. These previously overlooked materials also score in terms of speed since they allow many times greater speed than ferromagnets, so the frequencies could be shifted from the gigahertz range to the terahertz range. In short: The discovery has a special place in the rapidly growing new field of antiferromagnetic magnetoelectronics, which is also referred to as spintronics. Dr. Libor Šmejkal and his colleagues from Mainz University recently published their results in Science Advances.

    What is the Hall current?

    To understand Šmejkal's research, one must start with the Hall effect named after physicist Professor Edwin Hall. If a voltage is applied to conventional non-magnetic conductors such as copper, the current flows in the direction given by the electric field. However, if an external magnetic field is added, the current bends away from the applied direction. This additional cross component is known as the Hall current. The described Hall effect has been used for characterizing semiconductors, which shaped modern silicon electronics. Hall's second discovery: The internal magnetization of a ferromagnetic conductor such as iron can also lead to such a cross-current deflection. This made the Hall effect also one of the cornerstones of magnetoelectronics, a broad field that extends from sensor to memory technologies.

    The discovery of antiferromagnets, which are much more common in nature than ferromagnets, is attributed to Professor Louis Néel. In these the magnetic moments of the atoms are oriented in opposite directions. The effects observed in ferromagnets therefore cancel each other out – including the Hall current. The antiferromagnets behave towards the outside like the usual non-magnetic conductors and are therefore not applicable for magnetoelectronics.

    Unusual effect: Hall current in antiferromagets

    Nonmagnetic and antiferromagnetic crystals have been known for decades to be absent of Hall currents. Dr. Libor Šmejkal, however, found a crystal with an intriguing combination of nonmagnetic and antiferromagnetic atoms that produces a strong Hall current. Remarkably, crystals with antiferromagnetic and non-magnetic atoms are not uncommon in nature, but rather widespread.

    "Breaking with the conventional scientific wisdom requires extraordinary talents and skills," emphasized research group director Professor Jairo Sinova. "This is also the case with Dr. Libor Šmejkal. He is an exceptional physics talent who, as a freshly graduated doctorate, already enjoys the reputation of an international leader in his field." Šmejkal defended his PhD thesis only a few months ago, but already has given a dozen of invited talks at international conferences and published various papers in high-quality science journals. Immediately after the PhD defense, Šmejkal took the position of an independent team leader in the INSPIRE group at the JGU Institute of Physics.

    Image:
    https://download.uni-mainz.de/presse/08_physik_komet_hall_strom.jpg
    Electrons (gray wave packets) in antiferromagnetic (left) and nonmagnetic (middle) crystals move along the applied electric current (right). The combination of antiferromagnetic and nonmagnetic atoms (right) generates surprisingly transverse Hall motion of the electron. In the left and right panels, the blue and red shadings mark the positive and negative magnetization densities.
    ill./©: Libor Šmejkal

    Related links:
    https://www.sinova-group.physik.uni-mainz.de/ – Interdisciplinary Spintronics Research Group (INSPIRE) at JGU ;
    https://www.spice.uni-mainz.de/ – Spin Phenomena Interdisciplinary Center (SPICE) at JGU

    Read more:
    https://www.magazin.uni-mainz.de/9828_ENG_HTML.php – JGU MAGAZINE: "'We need to get out of our comfort zone'" (25 Jan. 2019) ;
    https://www.uni-mainz.de/presse/20402_ENG_HTML.php – press release "Demonstration of room-temperature spin-obit torque in NiMnSb" (21 July 2016) ;
    https://www.uni-mainz.de/presse/17562_ENG_HTML.php – press release "International team of scientists realizes a tunable spin-charge converter made of gallium-arsenide" (28 August 2014)


    Contact for scientific information:

    Dr. Libor Šmejkal
    INSPIRE group
    Institute of Physics
    Johannes Gutenberg University Mainz
    55099 Mainz, GERMANY
    phone +49 6131 39-23644
    e-mail: lsmejkal@uni-mainz.de
    https://www.sinova-group.physik.uni-mainz.de/team/libor-smejkal/


    Original publication:

    L. Šmejkal et al., Crystal time-reversal symmetry breaking and spontaneous Hall effect in collinear antiferromagnets, Science Advances 6:23, 5 June 2020,
    DOI: 10.1126/sciadv.aaz8809
    https://advances.sciencemag.org/content/6/23/eaaz8809.full


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    Criteria of this press release:
    Journalists, Scientists and scholars
    Electrical engineering, Information technology, Physics / astronomy
    transregional, national
    Research results, Scientific Publications
    English


     

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