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Example of the fractal structures in spin ice together with
a Mandelbrot set fractal on top of a photo of water ice. (Jonathan N.
Hallén/Cavendish Laboratory/University of Cambridge) |
Fractal patterns can be found everywhere from snowflakes to lightning to the jagged edges of coastlines. Beautiful to behold, their repetitive nature can also inspire mathematical insights into the chaos of the physical landscape.
A new example of these mathematical oddities has been
uncovered in a type of magnetic substance known as spin ice, and it could help
us better understand how a quirky behavior called a magnetic monopole emerges
from its unsettled structure.
Spin ices are magnetic crystals that obey similar structural
rules to water ices, with unique interactions governed by the spins of their
electrons rather than the push and pull of charges. As a result of this
activity, they don't have any one single low-energy state of minimal activity.
Instead, they almost hum with noise, even at insanely low temperatures.
A strange phenomenon emerges from this quantum buzz –
characteristics that act like magnets with just one pole. While they aren't
quite the hypothetical magnetic monopole particles some physicists think might
exist in nature, they behave in a similar enough manner that makes them worth
studying.
So an international team of researchers recently turned
their attention to a spin ice called dysprosium titanate. When small amounts of
heat are applied to the material, its typical magnetic rules break and
monopoles appear, with the north and south poles separating and acting
independently.
Several years ago a team of researchers identified signature
magnetic monopole activity in the quantum buzz of a dysprosium titanate spin
ice, yet the results left a few questions on the exact nature of these monopole
movements.
In this follow-up study, physicists realized the monopoles
weren't moving with complete freedom in three dimensions. Instead, they were
restricted to a 2.53-dimension plane inside a fixed lattice.
The scientists created complex models at the atomic scale to
show that the monopole movement was constrained in a fractal pattern that was
being erased and rewritten depending on the conditions and previous movements.
"When we fed this into our models, fractals immediately
emerged," says physicist Jonathan Hallén from the University of Cambridge.
"The configurations of the spins were creating a
network that the monopoles had to move on. The network was branching as a
fractal with exactly the right dimension."
This dynamic behavior explains why conventional experiments
had previously missed the fractals. It was the noise created around the
monopoles that eventually revealed what they were actually doing and the
fractal pattern they were following.
"We knew there was something really strange going
on," says physicist Claudio Castelnovo from the University of Cambridge in
the UK. "Results from 30 years of experiments didn't add up."
"After several failed attempts to explain the noise
results, we finally had a eureka moment, realizing that the monopoles must be
living in a fractal world and not moving freely in three dimensions, as had
always been assumed."
These sorts of breakthroughs can lead to step changes in the
possibilities of science and how materials like spin ices can be used: perhaps
in spintronics, an emerging field of study that could offer a next-gen upgrade
on the electronics we use today.
"Besides explaining several puzzling experimental
results that have been challenging us for a long time, the discovery of a
mechanism for the emergence of a new type of fractal has led to an entirely
unexpected route for unconventional motion to take place in three
dimensions," says theoretical physicist Roderich Moessner from the Max
Planck Institute for the Physics of Complex Systems in Germany.
Reference: Research Paper
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