New magnetic order

Physicists from the Jülich research center and the universities of Kiel and Hamburg have found a regular lattice of stable magnetic skyrmions – radial spiral structures, which are made up of atomic-scale spins.

These magnetic patterns have been found in large bulk materials before, but never on a nano-sized surface. The team of scientists, which published their findings Sunday in the journal Nature Physics, have theorized that these magnetic structures could lead to smaller and more efficient data storage units.

"If you had asked me five years ago if such a structure can form, I would have said no. But nature has its surprises," said Stefan Blügel, director of the Institute of Quantum Theory of Materials at the Peter Grünberg Institute at the Jülich national laboratory, and one of the paper's co-authors.

"We've discovered a new magnetic structure that is an extremely stable one," he told Deutsche Welle. "This structure is topologically-protected, and can't be destroyed very easily."

The future of spintronics

Skyrmions were first postulated by a British physicist in the 1950s, but were not found in nature until decades later. Physicists have speculated that these quasiparticles might assist the burgeoning research area of spintronics, which may power the next generation of consumer gadgets.

This new area physics research is being hailed as the successor of conventional electronics, based on transistor and semiconductor technology. In general, for over the last 50 years, the number of transistors that can be put on an integrated circuit doubles approximately every 18 to 24 months.

However, the number of transistors is now getting so large, on such a small space, that it's beginning to hit its physical limits, and will soon reach the size of individual atoms.

Conventional electronics have been based on harnessing the charge of electrons. When they move, they generate electric current, which can be used to transfer information. But electrons can do more than just travel in a linear direction - one quantum-mechanical characteristic is their intrinsic spin. Just as an ice skater twirls, so too do electrons.

Spintronics makes use of both the intrinsic spin of the electron and its fundamental electronic charge. In theory, scientists say that by harnessing this electronic spin as a way to store data at high-speed and low-power. Conceivably, that could make internal batteries, or even booting up a device, completely unecessary.

Earlier research in spintronics paved the way for solid-state flash memory commonly found nowadays in smartphones and digital cameras.

In the new study, the German scientists found the skyrmions in a thin layer of iron on iridium, where each spiral was made up of just 15 atoms.

Skyrmions on the surface

"It's extraordinary, because we found it on a surface instead of in bulk materials," Blügel said.

In 2009, scientists from Munich had found a similar structure in bulk materials, but this new one is 10 times smaller than that previous discovery.

"But it's a lot easier to observe and manipulate a magnetic structure on a surface, to write the codes 0 and 1 on the layer," Blügel adds.

"For us, it was surprising that this kind of structure formed after all, and that it was so very small," Blügel said.

Other phycisists have been impressed by the new finding.

"It's definitely meaningful for the field of magnetism," said Markus Garst who participated in the 2009 study, but didn't contribute to the recent study. "It's important that skyrmions were found in a different material as well. It's important for fundamental research and proves that these findings were not just an exotic exception."

Computer users will have to wait a bit longer

According to Ulrich Rössler from the Leibniz Institute for Solid State and Materials Research in Dresden, who has been researching these magnetic spirals for some time, these recent findings will mean that a new field of research may emerge, he wrote in an e-mail sent to Deutsche Welle.

"Such conditions consisting of countable units are quite rare in physics," he wrote.

But Rössler also added that it's too early to say how soon these findings can be put to use.

Blügel, one of the paper's authors, agreed, saying that it may be at least a decade before this research bears out into actual consumer products.

"This is important for storage as resistance comes into play when reading data," he said. "Maybe in about 10 to 15 years, this can be put to use in smaller storage units that can hold more data."

Author: Sarah Steffen
Editor: Cyrus Farivar