ALBA II - Workshop on Spintronics and synchrotron radiation
ALBA II - Workshop on Spintronics and synchrotron radiation
The event includes several presentations in the morning. In the afternoon, the workshop tries to stimulate via a round table a discussion of perspectives and interest of the spintronics community in Spain and ALBA users of materials and a reflection of what techniques, approaches and instrumentation would be important, covering the capabilities and use of the ARPES, XAS/XLD/XMLD/XMCD and XPEEM imaging instruments.
ZOOM Links for attendees will be available below before the event
- Session I 9:00 - 11:15h - access to ZOOM
- Session II 11:30 - 13:30h - access to ZOOM
- Session III & Roundtable 14:15 - 17:15h - access to ZOOM
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Session IConvener: Prof. Luis Hueso (CIC nanoGUNE)
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1
WelcomeSpeaker: Klaus Attenkofer
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2
Time- and spatially-resolved magnetization dynamics induced by spin-orbit torquesSpeaker: Prof. Pietro Gambardella (Department of materials, ETH Zurich )
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3
Spin-orbit and magnetic proximity effect in van dar Waals MaterialsSpeaker: Prof. Sergio O. Valenzuela (ICN2)
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4
Symmetry and topology in epitaxial Co films and nanostructuresSpeaker: Dr Jan Vogel (Neel Institute, CNRS Grenoble)
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5
Spintronics opportunities and directions at IMDEA Nanoscience: from Graphene-based spin-orbitronics to neuro nanotechnology applicationsSpeaker: Dr Julio Camarero (IMDEA Nanoscience & Univ. Autonoma Madrid)
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1
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11:15
Break
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Session IIConvener: Prof. Josep Fontcuberta (ICMAB-CSIC)
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6
Topological spin textures in thin films and multilayersSpeaker: Prof. Vincent Cros (Unité Mixte de Physique CNRS/Thales)
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7
Some insights into topological charges in magnetismSpeaker: Prof. Salvador Ferrer (Alba synchrotron light source)
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8
Some examples of research on spintronics at ICMABSpeaker: Dr Carlos Frontera (Institut de Ciència de Materials de Barcelona (ICMAB/CSIC))
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9
ALBA ARPES Capabilities for investigating spintronic materialsSpeaker: Dr Massimo Tallarida (ALBA-CELLS)
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10
ALBA XMCD Capabilities for investigating spintronic materialsSpeaker: Dr Manuel Valvidares
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6
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13:30
Break
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Session IIIConvener: Dr Stefania Pizzini (Institut Neel, CNRS Grenoble)
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11
ALBA PEEM capabilities for investigating spintronic materialsSpeaker: Dr Michael Joachim Ulrich Foerster
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12
ALBA TXM Capabilities for investigating spintronic materialsSpeaker: Dr Lucia Aballe Aramburu
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13
Pushing the limits of magnetic microscopy: time, space and analytics. Why and how?Speaker: Prof. Olivier Fruchart (SPINTEC IRIG / CEA Grenoble )
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14
Coherent X-rays for three dimensional imaging of magnetic systems and their dynamicsSpeaker: Dr Claire Donnelly (Cambridge University)
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15
New developments in synchrotron radiation based ferromagnetic resonance techniques
New developments in synchrotron radiation based ferromagnetic resonance techniques
David M. Burn1, Shilei Zhang2, Gerrit van der Laan1, Thorsten Hesjedal3
1Magnetic Spectroscopy, Diamond Light Source, Didcot, UK
2ShanghaiTech University, Shanghai, China
3Unversity of Oxford, Oxford, UKThe understanding of the magnetization dynamics of complex magnetic systems is the prerequisite for their controlled engineering, opening the door for the development of novel high-speed devices. A macroscopic understanding of the dynamic magnetization is commonly obtained through ferromagnetic resonance (FMR) measurements. Supported by micromagnetic simulations and theoretical modelling, some insight into their microscopic behavior is gained. X-ray detected ferromagnetic resonance (XFMR), on the other hand, provides a direct element-specific and time-resolved probe of the magnetization dynamics of technologically relevant layered spin valve and TMR structures [1,2]. Examples of XFMR measurements on such trilayer structures will be discussed.
To study the dynamics of topological magnetic systems, such as skyrmions, XFMR is unfortunately not suitable since the net magnetization probed by the x-ray beam vanishes. Magnetic skyrmions have shown a variety of novel features due to their unique topological nature, including new microwave excitation modes [3] such as clockwise and counterclockwise rotating, and breathing modes. Due to the periodic nature of the skyrmion lattice, resonant x-ray diffraction is very sensitive to probing this phase in, e.g., Cu2OSeO3 [4]. By combining resonant magnetic x-ray diffraction with FMR, diffractive FMR (DFMR) can give access to the real-space spin dynamics of a system. DFMR is a modal spectroscopy technique, potentially opening new pathways for the development of spintronic devices [5]. The technique will be introduced and discussed in the context of a cycloidal spin system.
References:
[1] G. van der Laan, J. Electron Spectrosc. Relat. Phenom. 220, 137 (2017).
[2] C. Klewe et al., Sync. Rad. News 33, 12 (2020).
[3] N. Nagaosa and Y. Tokura, Nat. Nanotechnol. 8, 899 (2013).
[4] S. L. Zhang et al., Phys. Rev. B 93, 21440 (2016).
[5] D.M. Burn et al., Nano Lett. 20, 345 (2020).Speaker: Prof. Thorsten Hesjedal -
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Spin Currents in AntiferromagnetsSpeaker: Prof. Axel Hoffman (a)
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11
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Open Roundtable
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