Stronger materials could bloom with new images of plastic flow
Date:
February 25, 2022
Source:
DOE/SLAC National Accelerator Laboratory
Summary:
Scientists have captured high-resolution images of a tiny aluminum
single-crystal sample as it transitioned from elastic to plastic
state.
FULL STORY ========================================================================== Imagine dropping a tennis ball onto a bedroom mattress. The tennis
ball will bend the mattress a bit, but not permanently -- pick the
ball back up, and the mattress returns to its original position and
strength. Scientists call this an elastic state.
==========================================================================
On the other hand, if you drop something heavy -- like a refrigerator
-- the force pushes the mattress into what scientists call a plastic
state. The plastic state, in this sense, is not the same as the plastic
milk jug in your refrigerator, but rather a permanent rearrangement of
the atomic structure of a material. When you remove the refrigerator, the mattress will be compressed and, well, uncomfortable, to say the least.
But a material's elastic-plastic shift concerns more than mattress
comfort.
Understanding what happens to a material at the atomic level when it transitions from elastic to plastic under high pressures could allow
scientists to design stronger materials for spacecraft and nuclear
fusion experiments.
Up to now, scientists have struggled to capture clear images of a
material's transformation into plasticity, leaving them in the dark about
what exactly tiny atoms are doing when they decide to leave their cozy
elastic state and venture into the plastic world.
Now for the first time, scientists from the Department of Energy's SLAC National Accelerator Laboratory have captured high-resolution images of
a tiny aluminum single-crystal sample as it transitioned from elastic to plastic state. The images will allow scientists to predict how a material behaves as it undergoes plastic transformation within five trillionths
of a second of the phenomena occurring. The team published their results
today in Nature Communications.
A crystal's last gasp To capture images of the aluminum crystal sample, scientists needed to apply a force, and a refrigerator was obviously
too large. So instead, they used a high-energy laser, which hammered
the crystal hard enough to push it from elastic to plastic.
==========================================================================
As the laser generated shockwaves that compressed the crystal, scientists
sent a high-energy electron beam through it with SLAC's speedy "electron camera," or Megaelectronvolt Ultrafast Electron Diffraction (MeV-UED) instrument. This electron beam scattered off aluminum nuclei and
electrons in the crystal, allowing scientists to precisely measure its
atomic structure. Scientists took multiple snapshots of the sample as
the laser continued to compress it, and this string of images resulted
in a sort of flip-book video -- a stop-motion movie of the crystal's
dance into the plasticity.
More specifically, the high-resolution snapshots showed scientists when
and how line defects appeared in the sample -- the first sign that a
material has been hit with a force too great to recover from.
Line defects are like broken strings on a tennis racket. For example,
if you use your tennis racket to lightly hit a tennis ball, your
racket's strings will vibrate a bit, but return to their original
position. However, if you hit a bowling ball with your racket, the
strings will morph out of place, unable to bounce back. Similarly,
as the high-energy laser struck the aluminum crystal sample, some rows
of atoms in the crystal shifted out of place. Tracking these shifts --
the line defects -- using MeV-UED's electron camera showed the crystal's elastic-to-plastic journey.
Scientists now have high-resolution images of these line defects,
revealing how fast defects grow and how they move once they appear,
SLAC scientist Mianzhen Mo said.
"Understanding the dynamics of plastic deformation will allow scientists
to add artificial defects to a material's lattice structure," Mo
said. "These artificial defects can provide a protective barrier to keep materials from deforming at high pressures in extreme environments."
UED's moment to shine
==========================================================================
Key to the experimenters' rapid, clear images was MeV-UED's high-energy electrons, which allowed the team to take sample images every half second.
"Most people are using relatively small electron energies in UED
experiments, but we are using 100 times more energetic electrons in our experiment," Xijie Wang, a distinguished scientist at SLAC, said. "At
high energy, you get more particles in a shorter pulse, which provides 3-dimensional images of excellent quality and a more complete picture
of the process." Researchers hope to apply their new understanding
of plasticity to diverse scientific applications, such as strengthening materials that are used in high- temperature nuclear fusion experiments. A better understanding of material responses in extreme environments is
urgently needed to predict their performance in a future fusion reactor, Siegfried Glenzer, the director for high energy density science, said.
"The success of this study will hopefully motivate implementing higher
laser powers to test a larger variety of important materials," Glenzer
said.
The team is interested in testing materials for experiments that will
be performed at the ITER Tokamak, a facility that hopes to be the first
to produce sustained fusion energy.
MeV-UED is an instrument of the Linac Coherent Light Source (LCLS) user facility, operated by SLAC on behalf of the DOE Office of Science. Part of
the research was performed at the Center for Integrated Nanotechnologies
at Los Alamos National Laboratory, a DOE Office of Science user
facility. Support was provided by the DOE Office of Science, in part
through the Laboratory Directed Research and Development program at SLAC.
========================================================================== Story Source: Materials provided by
DOE/SLAC_National_Accelerator_Laboratory. Original written by David
Krause. Note: Content may be edited for style and length.
========================================================================== Journal Reference:
1. Mianzhen Mo, Minxue Tang, Zhijiang Chen, J. Ryan Peterson,
Xiaozhe Shen,
John Kevin Baldwin, Mungo Frost, Mike Kozina, Alexander
Reid, Yongqiang Wang, Juncheng E, Adrien Descamps, Benjamin
K. Ofori-Okai, Renkai Li, Sheng-Nian Luo, Xijie Wang, Siegfried
Glenzer. Ultrafast visualization of incipient plasticity in
dynamically compressed matter. Nature Communications, 2022; 13
(1) DOI: 10.1038/s41467-022-28684-z ==========================================================================
Link to news story:
https://www.sciencedaily.com/releases/2022/02/220225163356.htm
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