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NEWS
17 May 2021

First nuclear detonation created 'impossible' quasicrystals

Their structures were once controversial. Now researchers have
discovered quasicrystals in the aftermath of a 1945 bomb test.

  * Davide Castelvecchi

 1. Davide Castelvecchi
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Red trinitite sample which contained the quasicrystal

This sample of red trinitite was found to contain a previously
unknown type of quasicrystal.Credit: Luca Bindi, Paul J. Steinhardt

Scientists searching for quasicrystals -- so-called 'impossible'
materials with unusual, non-repeating structures -- have identified
one in remnants of the world's first nuclear bomb test.

The previously unknown structure, made of iron, silicon, copper and
calcium, probably formed from the fusion of vapourized desert sand
and copper cables. Similar materials have been synthesized in the
laboratory and identified in meteorites, but this one, described in
Proceedings of the National Academy of Sciences on 17 May, is the
first example of a quasicrystal with this combination of elements^1.

Impossible symmetries

Quasicrystals contain building blocks of atoms that -- unlike those in
ordinary crystals -- do not repeat in a regular, brickwork-like
pattern. Whereas ordinary crystal structures look identical after
being translated in certain directions, quasicrystals have symmetries
that were once considered impossible: for example, some have
pentagonal symmetry, and so look the same if rotated by one-fifth of
a full twist.

Materials scientist Daniel Shechtman, now at the Technion Israel
Institute of Technology in Haifa, first discovered such an impossible
symmetry in a synthetic alloy in 1982. It had pentagonal symmetry
when rotated in each of various possible directions, something that
would occur if its building blocks were icosahedral -- that is, had a
regular shape with 20 faces. Many researchers initially questioned
Shechtman's findings, because it is mathematically impossible to fill
space using only icosahedrons. Shechtman ultimately won the 2011
Nobel Prize in Chemistry for the discovery.

At around the same time, Paul Steinhardt, a theoretical physicist now
at Princeton University in New Jersey, and his collaborators had
begun to theorize the possible existence of non-repeating 3D
structures. These had the same symmetry as an icosahedron, but were
assembled from building blocks of several different types, which
never repeated in the same pattern -- thus explaining why the
mathematics of symmetrical crystals had missed them. Mathematical
physicist Roger Penrose, now at the University of Oxford, UK, and
other researchers had previously discovered analogous patterns in two
dimensions, which are called Penrose tilings.

Steinhardt recalls the moment in 1982 when he first saw the
experimental data from Shechtman's discovery and compared it with his
theoretical predictions. "I stood up from my desk and went and looked
at our pattern, and you couldn't tell the difference," he says. "So
that was kind of an amazing moment."

In subsequent years, materials scientists synthesized several types
of quasicrystal, expanding the range of possible forbidden
symmetries. And Steinhardt and his colleagues later found the first
naturally occurring 'icosahedrite' in fragments from a meteorite
recovered on the Kamchatka Peninsula in Eastern Siberia. This
quasicrystal probably formed in a collision between two asteroids in
the early Solar System, Steinhardt says. Some of the lab-made
quasicrystals were also produced by smashing materials together at
high speed, so Steinhardt and his team wondered whether the
shockwaves from nuclear explosions might form quasicrystals, too.

'Slicing and dicing'

In the aftermath of the Trinity test -- the first ever detonation of a
nuclear bomb, which took place on 16 July 1945 at New Mexico's
Alamogordo Bombing Range -- researchers found a vast field of greenish
glassy material that had formed from the liquefaction of desert sand.
They dubbed this trinitite.

The plutonium bomb had been detonated on top of a 30-metre-high
tower, which was laden with sensors and their cables. As a result,
some of the trinitite that formed had reddish inclusions, says
Steinhardt. "It was a fusion of natural material with copper from the
transmission lines." Quasicrystals often form from elements that
would not normally combine, so Steinhardt and his colleagues thought
samples of the red trinitite would be a good place to look for
quasicrystals .

"Over the course of ten months, we were slicing and dicing, looking
at all sorts of minerals," Steinhardt says. "Finally, we found a tiny
grain." The quasicrystal has the same kind of icosahedral symmetry as
the one in Shechtman's original discovery.

"The dominance of silicon in its structure is quite distinct," says
Valeria Molinero, a theoretical chemist at the University of Utah in
Salt Lake City. "However, after many quasicrystals have been
synthesized in the lab," she says, "what I find truly intriguing is
that they are so scarce in nature." Steinhardt says this might be
because the formation of quasicrystals involves "unusual combinations
of elements and unusual arrangements".

Like most known quasicrystals, the trinitite structure seems to be an
alloy -- a metal-like material made up of positive ions in a sea of
electrons. This is unusual for silicon, which typically occurs in
rock in an oxidized form: reversing the oxidation would require
extreme conditions, such as the intense heat and pressure of a
shockwave, says Lincoln Hollister, a geoscientist at Princeton.

Steinhardt suggests that quasicrystals could be used for a kind of
nuclear forensic science, because they might reveal sites where a
covert nuclear test has occurred. Quasicrystals might also form in
other materials that were generated in violent conditions, such as
fulgurite, the material made when lightning strikes rock, sand or
other sediments. "The quasicrystal saga will continue!" says
Hollister.

doi: https://doi.org/10.1038/d41586-021-01332-0

References

 1. 1.

    Bindi, L. et al. Proc. Natl Acad. Sci. USA https://doi.org/
    10.1073/pnas.2101350118 (2021).

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          o Google Scholar

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