This item is interesting and clearly leads us to a great deal more
physics using the ultra cold system. The theory also confirms that
there is a lot of geometry at work here and my own ideas regarding
the construction of atoms fits into this world. Better it provides
an excellent confirmation tool for theoretical constructs that I
contemplate ultimately producing through simulation.
What is neat is to see a long ago theoretical result actually prove
up in the lab. The math said so, but what theorist or empiricist
ever really trust that? We are all too conscious that it is all made
up although I sometimes wonder.
All good and perhaps someone gets a Nobel Prize out of this.
Physicists
Prove Surprising Rule of Three
BY
NATALIE WOLCHOVER, QUANTA MAGAZINE
More
than 40 years after a Soviet nuclear physicist proposed an outlandish
theory that trios of particles can arrange themselves in an infinite
nesting-doll configuration, experimentalists have reported strong
evidence that this bizarre state of matter is real.
In
1970, Vitaly Efimov was manipulating the equations of quantum
mechanics in an attempt to calculate the behavior of sets of three
particles, such as the protons and neutrons that populate atomic
nuclei, when he discovered a law that pertained not only to nuclear
ingredients but also, under the right conditions, to any trio of
particles in nature.
While
most forces act between pairs, such as the north and south poles of a
magnet or a planet and its sun, Efimov identified an effect that
requires three components to spring into action. Together, the
components form a state of matter similar to Borromean rings, an
ancient symbol of three interconnected circles in which no two are
directly linked. The so-called Efimov “trimer” could
consist of a trio of protons, a triatomic molecule or any other set
of three particles, as long as their properties were tuned to the
right values. And in a surprising flourish, this hypothetical state
of matter exhibited an unheard-of feature: the ability to range in
size from practically infinitesimal to infinite.
“It’s
a pretty wild idea,” said Randy Hulet, a physics professor at Rice
University in Houston. “You get this infinite series of molecules.”
Efimov
had shown that when three particles come together, a special
confluence of their forces creates the Borromean rings effect: Though
one is not enough, the effects of two particles can conspire to bind
a third. The nesting-doll feature — called discrete scale
invariance — arose from a symmetry in the equation describing the
forces between three particles. If the particles satisfied the
equation when spaced a certain distance apart, then the same
particles spaced 22.7 times farther apart were also a solution. This
number, called a “scaling factor,” emerged from the mathematics
as inexplicably as pi, the ratio between a circle’s circumference
and diameter.
“It’s
like layers of an onion,” Hulet said. “You see molecules at one
layer. Peel the layer away, and you see that there’s a molecule
there 22.7 times smaller. Every time you peel away a layer, you find
another molecule.”
Efimov
published his theory in a Soviet journal as well as the
Western publication Physics Letters B. At first, almost no one
believed it.
“In
the West, these ideas were greeted with great skepticism,”
said Eric Braaten, a theoretical physicist at Ohio State
University who was in high school when Efimov’s paper appeared.
Theorists
waded into the equations in search of an error. But instead, Braaten
said, “they became convinced that it was true.”
But
even with airtight logic, the theory did not necessarily have to
manifest itself in nature. “I thought it was way too weird to have
any basis in reality,” said Chris Greene, a physicist at
Purdue University who studies “few-body” quantum systems, which
consist of only a few particles.
And
for decades, no one knew whether the theory described real matter. As
researchers mulled over where to look for Efimov trimers, Efimov
himself emigrated west and became a teaching professor at the
University of Washington, where he achieved renown more for shooting
a gun in class during a lesson on inelastic collisions than for his
outlandish theory.
Because
the Efimov state is weakly bound and is usually overpowered by other
forces, observing it requires precise tuning. Particles must have the
peculiar quantum property of being able to collide when they are far
apart, beyond the range of the force between them–a situation
analogous to Earth ricocheting off a distant star whose gravity it
does not feel. And the particles must have too little energy to
wiggle out of formation.
Vitaly
Efimov, a professor at the University of Washington — pictured
during a visit to Innsbruck, Austria, in 2009 — developed his
theory of trimers while working as a nuclear physicist in the Soviet
Union in 1970. Image: Flatz/University of Innsbruck
Some
physicists suspected that an accidental fine-tuning in nature might
cause the Efimov state to arise in the guise of the helium-4 atom and
in a carbon isotope called the Hoyle state that forms in stars and
begets many other elements. But these nuclei were too complex for
controlled studies.
In
1999, Greene realized that the properties necessary for the Efimov
state could be tuned by hand in newly developed ultracold optical
traps. Atoms inside these apparatuses could be laser-cooled to a
fraction of a degree above absolute zero, limiting their wiggling
ability, and a magnetic field could be applied to make them collide
at great distances.
Rudi
Grimm and his group at the University of Innsbruck in Austria
managed to create an Efimov trimer for the first time in 2006,
building it from a trio of cesium atoms cooled to 10-billionths of a
degree above absolute zero. It was a long-awaited triumph for Efimov,
who, Grimm recalled, became very emotional when he heard the news.
But
the result did not decisively prove the theory.
“With
just one example, it’s very difficult to tell if it’s a Russian
nesting doll,” said Cheng Chin, a professor of physics at the
University of Chicago who was part of Grimm’s group in 2006. The
ultimate proof would be an observation of consecutive Efimov trimers,
each enlarged by a factor of 22.7. “That initiated a new race” to
prove the theory, Chin said.
Eight
years later, the competition to observe a series of Efimov states has
ended in a photo finish. “What you see is three groups,
in three different countries, reporting these multiple Efimov states
all within about one month,” said Chin, who led one of the groups.
“It’s totally amazing.”
Grimm’s
team observed a second Efimov trimer made of cesium atoms, reporting
the results May 12 in Physical Review Letters. The 2006 trimer
spanned the width of 1,000 hydrogen atoms, requiring the new one to
measure a full micrometer across — “a gigantic molecule,” Grimm
said.
Each
22.7-times larger Efimov state is also 22.7-squared times weaker,
requiring the optical trap to be cooled even further to allow the new
state to form. Grimm’s group perfected its techniques and detected
the state at the very edge of experimental limits.
Meanwhile,
the two other groups managed to observe three consecutive Efimov
states by taking advantage of a footnote in the theory: When a trimer
is built from a mixture of different particles rather than an
identical set, the scaling factor of 22.7 decreases according to the
particles’ relative masses. In other words, nesting dolls made of
atomic mixtures become closer in size, enabling more of them to be
observed within the experimental window.
Both
Chin’s team and a group led by Matthias Weidemüller at the
University of Heidelberg observed Efimov trimers of three different
sizes, each made of two cesium atoms and a much lighter lithium atom.
Chin’s group posted its paper online in February, and the
Heidelberg scientists followed with theirs in March. Both papers,
which are still under peer review, reported a scaling factor right
around 4.9 for the relative sizes of their trimers — exactly the
adjustment to 22.7 predicted by the theory.
“We
are very excited about this result,” Chin said. “In the
complicated molecular world, there’s a new law.”
The
law is a geometric progression of evermore-enormous trios of
particles, spanning in a theoretically infinite sequence from the
quantum scale to (if the particles were cold enough) the size of the
universe and beyond. “Although we didn’t see an infinite number
of them, there’s pretty strong evidence when you see three in a
row,” Chin said.
For
some, the results mark the end of an era, as well as a starting
point.
“For
the classic Efimov scenario, the story is now basically completed,”
Grimm said. But as a paradigm for looking at few-body phenomena in
cold atoms, he said, “it’s like the tip of the iceberg.”
The
Efimov state is the most elementary effect in few-body physics, the
researchers said, but there are countless others that seem to
influence the arrangements of small numbers of atoms: four-, five-
and six-body interactions and so on. Scientists think it might be
possible to augment some of these effects in ultracold optical traps
to produce new bulk properties of matter, such as exotic forms of
superconductivity. An improved understanding of few-body physics
would also feed into models of more complex systems involving many
more particles.
But
direct practical applications of the Efimov state are limited. For
the researchers who have studied the odd yet elegant idea for
decades, the main driver of the new research, and its chief delight,
is having a final proof.
“It
is satisfying to really see this magic number, 22.7, coming out,”
said Braaten, who was not involved in the new studies. “There was
indirect evidence that all this worked, but actually seeing this
discrete scaling factor explicitly in experiment — it’s
comforting.”
A hundred years ago Nicola Tesla said the secret of the universe was in the three, six, and nine.
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