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Nanoscale spin waves can replace microwaves

News: Aug 29, 2011

A group of scientists from the University of Gothenburg and the Royal Institute of Technology (KTH) have become the first group in the world to demonstrate that theories about nanoscale spin waves agree with observations. This opens the way to replacing microwave technology in many applications, such as mobile phones and wireless networks, by components that are much smaller, cheaper, and that require less resources. The study has been published in the scientific journal Nature Nanotechnology.

“We have been in competition with two other research groups to be the first to confirm experimentally theoretical predictions that were first made nearly 10 years ago. We have been successful due to our method for constructing magnetic nanocontacts and due to the special microscope at our collaborators’ laboratory at the University of Perugia in Italy”, says Professor Johan Åkerman of the Department of Physics, University of Gothenburg, where he is head of the Applied Spintronics group.

Spin waves from one nanocontact.The aim of the research project, which started two years ago, has been to demonstrate the propagation of spin waves from magnetic nanocontacts. Last autumn, the group was able to demonstrate the existence of spin waves with the aid of electrical measurements, and the results were published in the scientific journal Physical Review Letters. The new results have been published in Nature Nanotechnology.

The research group has used one of the three advanced spin wave microscopes in the world, at the university in the Italian town of Perugia, to visualise the motion. The microscope makes it possible to see the dynamic properties of components with a resolution of approximately 250 nanometre.

Magnonics may give smaller and cheaper components

The results have opened the way for a new field of research known as “magnonics”, using nanoscale magnetic waves.

“I believe that our results will signal the start of a rapid development of magnonic components and circuits. What is particularly exciting is that these components are powered by simple direct current, which is then converted into spin waves in the microwave region. The frequency of these waves can be directly controlled by the current. This will make completely new functions possible”, says Johan Åkerman, who is looking forward to exciting developments in the next few years.

Its magneto-optical and metallic properties mean that magnonic technology can be integrated with traditional microwave-based electronic circuits, and this will make completely untried combinations of the technologies possible. Magnonic components are much more suitable for miniaturisation than traditional microwave technology.
The article, Direct observation of a propagating spin wave induced by spin-transfer torque, has been published online in the scientific journal Nature Nanotechnology.
The article is available at: http://www.nature.com/nnano/journal/vaop/ncurrent/abs/nnano.2011.140.html

<iframe width="276" height="237" src="http://www.youtube.com/embed/PFnLRXzl4uI?rel=0" frameborder="0" allowfullscreen></iframe>

Contact:
Professor Johan Åkerman, Department of Physics, University of Gothenburg
+46 (0)31 786 9147
+46 (0)70 710 4360
johan.akerman@physics.gu.se

Figure legend: Spin waves spread from a magnetic nanocontact like rings on water.

Animated simulations of spin waves above can also be found on our YouTube channel:

http://youtu.be/EGV25mUxnmk
A simulation of six magnetic nanocontacts placed in a circle to illustrate how the nanocontacts can be placed in freely chosen patterns. All the signals synchronise in this case through the spin waves that propagate through the magnetic film.

http://youtu.be/PFnLRXzl4uI
The simulation of magnetic nanocontacts shows how spin waves spread like rings on water. The nanocontact has a diameter of 40 nanometre and the spin waves are created in a thin film of nickel-iron alloy, 3 nanometre thick.

 

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