(left) atoms present in the 2D material.
(right) photos of single atoms. Credit: The Grainger College of Engineering at
the University of Illinois Urbana-Champaign
Most
people envision vibration on a large scale, like the buzz of a cell phone
notification or the oscillation of an electric toothbrush. But scientists think
about vibration on a smaller scale—atomic, even.
In
a first for the field, researchers from The Grainger College of Engineering at
the University of Illinois at Urbana-Champaign have used advanced imaging
technology to directly observe a previously hidden branch of vibrational
physics in 2D materials. Their findings, published in Science, confirm the existence of a
previously unseen class of vibrational modes and present the highest resolution
images ever taken of a single atom.
Two-dimensional
materials are a promising candidate for next-generation electronics because
they can be scaled down in size to thicknesses of just a few atoms while
maintaining desirable electronic properties. A route to these new electronic
devices lies at the atomic level,
by creating so-called Moiré systems—stacks of 2D materials whose lattices do
not match, for reasons such as the twisting of atomic layers.
Moiré
phonons are low-frequency vibrational modes unique to twisted 2D bilayer
materials. Because heat is a consequence of vibrational patterns, examining
different patterns among phonons can help scientists better understand heat
expression. Like phonons, phasons are vibrational modes associated with atomic
movement, and they are thought to explain some of the unique and desirable
properties seen in twisted 2D materials. But until now, phasons in 2D materials
had eluded direct observation, rendering predictions about their existence
purely hypothetical.
"You
can't easily get rid of phasons; that's the blessing and the curse," said
Pinshane Huang, a professor of materials science & engineering and the
senior author of the paper. "They've always been hanging around
undetected, changing the properties of 2D moiré materials."
Huang's
interest in electron microscopy prompted
the question: Can new advancements in imaging technology be used to visualize
local vibrational modes such as phasons? To investigate this possibility, Huang
joined forces with Yichao Zhang, then a postdoctoral researcher studying
nanoscale heat transport and the study's lead author.
"Our
central goal was to see heat by looking at an atom," Huang said.
"This works by getting such high spatial resolution that the vibrations of
atoms change how blurry the atoms appear. These motions are tiny, and we are
literally able to look at one atom at a time and see how they are moving due to
heat."
To
obtain these images, the team relied on electron ptychography, a recently
developed technique that massively enhances the resolution of existing
microscopes. By achieving picometer-scale spatial resolution, the researchers
directly observed thermal vibrations in twisted bilayer WSe2 atoms.
"At
the start of my career, the highest resolution we thought was possible was just
under one angstrom," Huang said. "But when ptychography rolled around
a few years ago, we started seeing numbers as low as 0.2 angstroms. That got us
thinking, 'hey, heat vibrates atoms by roughly 0.05 angstroms.' Being able to
see heat is one example of how a monumental leap in resolution fundamentally changes what
microscopes can do."
The
Illinois Grainger engineers anticipate a future in which phasons may be used to
create electronics that function differently than current iterations.
"One potential application of this technique is making materials that are better heat conductors," Zhang said. "We could look at a single atom and identify a defect that's preventing the material from cooling down more efficiently. This could lead to better thermal management techniques at the atomic scale. Looking at atoms one by one and how they respond to thermal vibrations will give us that type of fundamental knowledge."
Source: Good vibrations: Scientists use imaging technology to visualize heat
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