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  Polarizing an antiferromagnet by optical engineering of the crystal field

Disa, A., Fechner, M., Nova, T. F., Liu, B., Foerst, M., Prabhakaran, D., et al. (2020). Polarizing an antiferromagnet by optical engineering of the crystal field. Nature Physics, 16(9), 937-941. doi:10.1038/s41567-020-0936-3.

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Supplementary information (Figs. 1–6, Tables 1–3 and refs. 1–25 [pdf]), Source data (Data for measured Faraday rotation and circular dichroism plotted in Fig. 4, Data for measured temperature, field and frequency dependences plotted in Fig. 5, Data for induced magnetization from experiment and theory plotted in Fig. 6 [dat])
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 Creators:
Disa, A.1, 2, Author           
Fechner, M.1, Author           
Nova, T. F.1, Author           
Liu, B.1, Author           
Foerst, M.1, Author           
Prabhakaran, D.3, Author
Radaelli, P. G.3, Author
Cavalleri, A.1, 2, 3, Author           
Affiliations:
1Quantum Condensed Matter Dynamics, Condensed Matter Dynamics Department, Max Planck Institute for the Structure and Dynamics of Matter, Max Planck Society, ou_1938293              
2The Hamburg Centre for Ultrafast Imaging, ou_persistent22              
3Clarendon Laboratory, Department of Physics, Oxford University, ou_persistent22              

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 Abstract: Strain engineering is widely used to manipulate the electronic and magnetic properties of complex materials. For example, the piezomagnetic effect provides an attractive route to control magnetism with strain. In this effect, the staggered spin structure of an antiferromagnet is decompensated by breaking the crystal field symmetry, which induces a ferrimagnetic polarization. Piezomagnetism is especially appealing because, unlike magnetostriction, it couples strain and magnetization at linear order, and allows for bi-directional control suitable for memory and spintronics applications. However, its use in functional devices has so far been hindered by the slow speed and large uniaxial strains required. Here we show that the essential features of piezomagnetism can be reproduced with optical phonons alone, which can be driven by light to large amplitudes without changing the volume and hence beyond the elastic limits of the material. We exploit nonlinear, three-phonon mixing to induce the desired crystal field distortions in the antiferromagnet CoF2. Through this effect, we generate a ferrimagnetic moment of 0.2 μB per unit cell, nearly three orders of magnitude larger than achieved with mechanical strain.

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Language(s): eng - English
 Dates: 2020-01-072020-05-112020-06-222020-09-09
 Publication Status: Issued
 Pages: 5
 Publishing info: -
 Table of Contents: -
 Rev. Type: Peer
 Identifiers: arXiv: 2001.00540
DOI: 10.1038/s41567-020-0936-3
 Degree: -

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Grant ID : 319286
Funding program : Funding Programme 7 (FP7)
Funding organization : European Commission (EC)
Project name : We thank J. Chen for help preparing the samples and assistance with the optical experiment. This work received funding from the European Research Council under the European Union’s Seventh Framework Programme (FP7/2007–2013)/ERC (grant agreement no. 319286 (QMAC)) and the Cluster of Excellence ‘CUI: Advanced Imaging of Matter’ of the Deutsche Forschungsgemeinschaft (DFG), EXC 2056, project ID 390715994. Work done at the University of Oxford was funded by EPSRC grant no. EP/M020517/1, entitled Oxford Quantum Materials Platform Grant. A.S.D. was supported by a fellowship from the Alexander von Humboldt Foundation.
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Source 1

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Title: Nature Physics
  Other : Nat. Phys.
Source Genre: Journal
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Publ. Info: London : Nature Pub. Group
Pages: - Volume / Issue: 16 (9) Sequence Number: - Start / End Page: 937 - 941 Identifier: ISSN: 1745-2473
CoNE: https://pure.mpg.de/cone/journals/resource/1000000000025850