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These Magnetic Whirlpools Could Unlock True Random Numbers 

It’s been over a decade since stories concerning skyrmions—tiny, swirling magnetic spin patterns in thin films—began to appear in the media. These spinning magnetic Whirlpools had been proposed by British physicist Tony Skyrme, from whence the name derives, almost 60 years earlier, but they suddenly seemed like a game-changer for magnetic Whirlpools data storage systems.

Now, a group of Brown University academics has discovered a new way to employ skyrmions for a completely different purpose: creating real random numbers, which are helpful in encryption, secure communications, and probabilistic computing.

Electron spins in ultrathin materials generate skyrmions. Consider electron spins as small arrows pointing up, down, or anywhere in between, expressing the particle’s magnetic orientation (or magnetic moment). When some very thin, virtually two-dimensional materials are at their lowest energy states, they have a phenomenon called perpendicular magnetic anisotropy, which means that the magnetization orientation has a preferred direction. Some electron spins will flip if you add electricity or a magnetic field to a 2D substance in this state. As a result, the electrons in the vicinity jostle around, forming magnetic whirlpools around the flipped electron: a skyrmion.

While skyrmions were previously thought to be a promising future data storage medium, various issues arose along the road. One complication is a phenomenon that arises when a magnetic field is placed perpendicular to a conductor’s plane. The current flow in the conductor alters, resulting in a change in voltage that may be measured. Despite its enigmatic nature, the so-called Hall effect is now a critical component of GPS technology, smartphone components, and brushless DC motors.

It’s been almost a decade since news items began to appear about something in data storage called skyrmions—tiny, swirling magnetic spin patterns in thin films. These spinning Magnetic Whirlpools had been proposed over 60 years ago by British physicist Tony Skyrme—from whom the name derives—but suddenly they seemed a potential game-changer for magnetic Whirlpools data storage systems.

In part because the Hall effect introduced extreme difficulties in skyrmion data-storage prototypes, the idea emerged to use the seeming detriment to the system as a benefit instead.

Researchers started working on ideas like exploiting Brownian motion (the continual movement of atoms and molecules as they bounce off one another in a liquid or gas) of skyrmions in devices like a reshuffler for stochastic computing, which uses random bits to calculate using basic circuits. Regrettably, such devices necessitated complex geometry and offered their own set of challenges in terms of precise control of skyrmion motion.

Kang Wang, a postdoctoral research associate at Brown University, was unfazed by this new line of research and was inspired by it.

While skyrmions once held promise as possible future data-storage media, some complications cropped up along the way. One complication concerns a phenomenon that occurs when you place a magnetic field perpendicular to the plane of a conductor. The current flow in the conductor shifts, creating a measurable change in voltage. And though it may sound arcane, the so-called Hall effect is today the essential element behind some GPS technology, smartphone components, and brushless DC motors.

In part because the Hall effect introduced extreme difficulties in skyrmion data-storage prototypes, the idea emerged to use the seeming detriment to the system as a benefit instead.

Researchers began working on ideas such as using Brownian motion (the constant movement of atoms and molecules as they bounce off one another in a liquid or a gas) of skyrmions for use in devices such as a reshuffler for stochastic computing, in which random bits are used to calculate via simple circuits. Unfortunately, such devices also required complex geometry and posed their own problems in exercising precise control over skyrmion motion.

Undaunted, Kang Wang, a postdoctoral research associate at Brown University, was inspired by this latest line of research.

“We came up with the idea of taking advantage of defects in magnets, which are usually considered to be a weakness in traditional skyrmion devices, and introducing the local dynamic behavior of a skyrmion to make it a robust true random-number generator,” says Wang.

Brown University researchers created magnetic Whirlpools thin films by creating small flaws in the material’s atomic lattice. The skyrmions are trapped in these flaws, which are known as pinning centers, by altering the growth conditions for the films, such as by modifying layer thicknesses in typical locations.

The nanosize whirlpools begin to change in size randomly as the skyrmions are held in these pinning centers. While one piece of the skyrmion is pinned to one pinning center, the rest of it hops back and forth, wrapping around two nearby pinning centers, one closer and one farther away. The random switching of skyrmions from a large to a small diameter can be monitored.

The Hall effect is used to measure the change in skyrmion size. The voltage changes as the size of the skyrmion changes to the point where it can be measured. The result of these random voltage fluctuations is a string of random digits.

The researchers’ preliminary simulation experiments show that this strategy should be easily scalable.

“The skyrmion system can be easily made with simple sample growth and fabrication processes,” says Wang. “Moreover, the skyrmion true random-number generator can be integrated with other skyrmion devices in a single die for the implementation of in-memory and computing architectures.”

It’s been almost a decade since news items began to appear about something in data storage called skyrmions—tiny, swirling magnetic spin patterns in thin films. These spinning magnetic Whirlpools had been proposed over 60 years ago by British physicist Tony Skyrme—from whom the name derives—but suddenly they seemed a potential game-changer for magnetic data-storage systems.

Now a team of researchers at Brown University has found a novel way to use skyrmions for an entirely new application: generating true random numbers, which are useful in cryptography, secure communications, and probabilistic computing.

Skyrmions are generated from electron spins in ultrathin materials. Think of electron spins as tiny arrows representing the particle’s magnetic orientation (or magnetic moment) as it points up, down, or somewhere in between. When some extremely thin, essentially two-dimensional materials are in their lowest energy states, they possess a property known as perpendicular magnetic anisotropy, which means the magnetization orientation has a preferred direction. If you apply electricity or a magnetic field to a 2D material in this state, some electron spins will flip. As a result, the surrounding electrons are jostled around, creating magnetic whirlpools around the flipped electron: a skyrmion.

While skyrmions once held promise as possible future data-storage media, some complications cropped up along the way. One complication concerns a phenomenon that occurs when you place a magnetic field perpendicular to the plane of a conductor. The current flow in the conductor shifts, creating a measurable change in voltage. And though it may sound arcane, the so-called Hall effect is today the essential element behind some GPS technology, smartphone components, and brushless DC motors.

In part because the Hall effect introduced extreme difficulties in skyrmion data-storage prototypes, the idea emerged to use the seeming detriment to the system as a benefit instead.

Researchers began working on ideas such as using Brownian motion (the constant movement of atoms and molecules as they bounce off one another in a liquid or a gas) of skyrmions for use in devices such as a reshuffler for stochastic computing, in which random bits are used to calculate via simple circuits. Unfortunately, such devices also required complex geometry and posed their own problems in exercising precise control over skyrmion motion.

Undaunted, Kang Wang, a postdoctoral research associate at Brown University, was inspired by this latest line of research.

“We came up with the idea of taking advantage of defects in magnets, which are usually considered to be a weakness in traditional skyrmion devices, and introducing the local dynamic behavior of a skyrmion to make it a robust true random-number generator,” says Wang.

The Brown researchers fabricated magnetic thin films using a technique that produced subtle defects in the material’s atomic lattice. These defects are created by manipulating the growth conditions for the films, such as by modifying layer thicknesses in typical regions to trap the skyrmions in these defects, known as pinning centers.

By holding the skyrmions in these pinning centers, the nanosize whirlpools begin to fluctuate randomly in size. While one section of the skyrmion is held tightly to one pinning center, the rest of the skyrmion jumps back and forth, wrapping around two nearby pinning centers, one closer and one farther away. This random jumping back and forth of the skyrmions from a large diameter to a small diameter can be measured. Measuring these fluctuations is what generates the random numbers.

The change in skyrmion size is measured through the Hall effect. When the skyrmion size changes, the voltage changes to the point where it can be easily measured. These random voltage changes are then used to produce a string of random digits.

Initial simulation studies carried out by the researchers indicate that this approach should be easily scalable.

“The skyrmion system can be easily made with simple sample growth and fabrication processes,” says Wang. “Moreover, the skyrmion true random-number generator can be integrated with other skyrmion devices in a single die for the implementation of in-memory and computing architectures.”

Wang is confident that the technology for a skyrmion-based random-number generator may not be that far off.

“This could be used fairly soon,” says Wang. “Key development landmarks may be better control of the spatial energy landscape confining a skyrmion, further improvement of operation speed and the output signals from the device, and integration of the skyrmion system with integrated circuits for signal readout and processing.”

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Written by Emma Ava

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