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PD Dr. Guido Meier
Guido Meier
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Original Publication

1.
Lars Bocklage, Christian Swoboda, Kai Schlage, Hans-Christian Wille, Liudmila Dzemiantsova, Saša Bajt, Guido Meier, and Ralf Röhlsberger
Spin Precession Mapping at Ferromagnetic Resonance via Nuclear Resonant Scattering of Synchrotron Radiation

Ultrafast tracking of electron spins

Diagnostics for the information technology of tomorrow

April 22, 2015

Our present digital information processing and storage is based on two properties of the electron. The first is its charge, which is used in electronic circuits to process information. The second is its spin, which represents the information stored on a magnetic hard disk. Current research approaches attempt to make use of the charge and the spin of the electron simultaneously. This approach could improve functionality, capacity, speed, and energy consumption of today’s information technology.
A microscope image of the magnetic sample, showing the bright track of the X-ray beam. Zoom Image
A microscope image of the magnetic sample, showing the bright track of the X-ray beam.

Researchers from DESY, the Max Planck Institute for the Structure and Dynamics of Matter, and the University of Hamburg have now made a big step towards tracking the electron spin at very high frequencies, which are technologically important. The team used the extremely brilliant X-rays generated at DESY's PETRA III facility to read out a nuclear sensor placed in the investigated magnetic material. In this way they could determine the motion of the spins, as the researchers report in the journal Physical Review Letters.

”The actual orbit of the spin is important as it determines many of the spin related effects that are under research now and proposed for new functional devices“, explains main author Lars Bocklage from DESY, who is also a member of the Hamburg Centre for Ultrafast Imaging (CUI). “Especially for data processing and mobile communication high frequencies are of importance. But even the fastest microscopy techniques available to determine spin motions reach their limit when it comes to the Gigahertz regime used in the present experiment.” A Gigahertz corresponds to a billion cycles per second.

The trick in the new work is the use of a certain isotope of iron that contains one neutron more than the most prevalent iron isotope in nature. It can absorb X-rays of a specific energy, but reemits the X-ray after a very short time. This technique is called nuclear resonant scattering. The team around Bocklage found out in which way the X-ray emission is influenced by the motion of the spin. “This way the spin leaves a fingerprint in the photons emitted from the iron isotope, and the orbit of the spin can be identified,” explains Bocklage.

The system that was investigated is a 13 nanometers (millionths of a millimeter) thin ferromagnetic film of nickel and iron, an alloy called permalloy. The material was excited with an external high-frequency magnetic field that initiates a precession of the spins. This means the spin axes reel like a child's top that has been nudged sideways. The exact motion of the spin was not known up to now. The investigations show that the shape and the amplitude can be precisely determined.

“The spins perform an elliptical motion in the thin film which has many implications for the research fields of spintronics, spincaloritronics, and magnonics as well as for the theoretical models that describe spin related effects,” reports Bocklage. “With the given nuclear scattering technique and the findings on the spin motion, systems can be tuned to optimize the orbit of the spin and with it the functionality of future spin-based devices.”

 
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