2018
DOI: 10.1103/physrevlett.120.037202
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Chirality in Magnetic Multilayers Probed by the Symmetry and the Amplitude of Dichroism in X-Ray Resonant Magnetic Scattering

Abstract: Chirality is central to understand many fundamental mechanisms in various domains of physics and chemistry. In condensed matter, a large variety of physical phenomena hinge on the emergence of these complex chiral windings of order parameters, their observation and subsequently their control especially in magnetism and spintransport at the nanoscale. The ability to probe the nature of these chiral magnetic textures has now become a crucial element of modern magnetism and is therefore essential to gain a deeper… Show more

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Cited by 66 publications
(56 citation statements)
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“…The effect is entirely due to the term of intensity related to the interference between the charge and the magnetic scattering. This contrasts with the observations made in other magnetic systems in which their out-of-plane magnetization component has a significant magnitude, whose asymmetries in their magnetization distribution were detected solely by the pure magnetic scattering term [17,22]. The demonstrated sensitivity of CXRMS to the chirality of 2D magnetic vortex opens the door to the study of more complicated systems where the potential capabilities of the technique, like non-invasive detection, element sensitivity, time resolved dynamics and/or magnetic superlattice order sensitivity can be exploited to the study of 2D magnet arrays even at smaller scales than the presented in this experiment.…”
Section: Discussioncontrasting
confidence: 96%
“…The effect is entirely due to the term of intensity related to the interference between the charge and the magnetic scattering. This contrasts with the observations made in other magnetic systems in which their out-of-plane magnetization component has a significant magnitude, whose asymmetries in their magnetization distribution were detected solely by the pure magnetic scattering term [17,22]. The demonstrated sensitivity of CXRMS to the chirality of 2D magnetic vortex opens the door to the study of more complicated systems where the potential capabilities of the technique, like non-invasive detection, element sensitivity, time resolved dynamics and/or magnetic superlattice order sensitivity can be exploited to the study of 2D magnet arrays even at smaller scales than the presented in this experiment.…”
Section: Discussioncontrasting
confidence: 96%
“…By changing the energy of the incident X-rays, we varied systematically the attenuation depth to perform a quasi-tomographic mapping of the magnetic state. This goes well beyond previous depth-dependent REXS studies, which pursued chemical modifications and the identification of the presence of magnetic phases only (12,14,45).…”
Section: Resultsmentioning
confidence: 67%
“…X-rays are perfectly matched to the length scales of the magnetic periodicities, suggesting that studies of the spin structure with increasing depth as controlled by the scattering angle or the photon energy should be possible (12). In addition, representing chiral spin textures, the dichroism of soft X-ray scattering permits reconstruction of the full 3D spin order, providing information on gradual variations (13,14). Last but not least, high-quality single crystals are available as a key precondition for meaningful experimental results.…”
mentioning
confidence: 99%
“…The iDMI emerges in HM/FM interfaces owing broken spatial inversion symmetry which determines its sign and direction, whilst the iDMI magnitude depends on the SOC [14][15][16]. In this sense, different combinations of HM/FM interfaces have been investigated to obtain strong iDMI amplitudes and distinct signs to stabilize skyrmions and define their chirality [17][18][19]. Although isolated skyrmions have been observed recently at room temperature in this kind of systems, their nucleation and stabilization in most cases require external magnetic field and/or electrical current [20][21][22].…”
mentioning
confidence: 99%