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Home > Press > Quantum physics on tap - Nano-sized faucet offers experimental support for longstanding quantum theory

This schematic drawing shows a nanoscale faucet: a long cylindrical channel connected to a container of superfluid helium. When vacuum pressure is applied to one end of the faucet's opening-a nanopore-helium atoms (represented here as pink balls) flow through, and are collected and measured as they spread out. An incredibly sensitive detector is needed to register the hundredths of nanograms of helium that flow through each second. CREDIT: Adrian Del Maestro)
This schematic drawing shows a nanoscale faucet: a long cylindrical channel connected to a container of superfluid helium. When vacuum pressure is applied to one end of the faucet's opening-a nanopore-helium atoms (represented here as pink balls) flow through, and are collected and measured as they spread out. An incredibly sensitive detector is needed to register the hundredths of nanograms of helium that flow through each second. CREDIT: Adrian Del Maestro)

Abstract:
We all know intuitively that normal liquids flow more quickly as the channel containing them tightens. Think of a river flowing through narrow rapids.

Quantum physics on tap - Nano-sized faucet offers experimental support for longstanding quantum theory

Montreal, Canada | Posted on May 16th, 2015

But what if a pipe were so amazingly tiny that only a few atoms of superfluid helium could squeeze through its opening at once? According to a longstanding quantum-mechanics model, the superfluid helium would behave differently from a normal liquid: far from speeding up, it would actually slow down..

For more than 70 years, scientists have been studying the flow of helium through ever smaller pipes. But only recently has nanotechnology made it possible to reach the scale required to test the theoretical model, known as the Tomonaga-Luttinger theory (after the scientists who developed it).

Now, a team of McGill University researchers, with collaborators at the University of Vermont and at Leipzig University in Germany, has succeeded in conducting experiments with the smallest channel yet - less than 30 atoms wide. In results published online today in Science Advances, the researchers report that the flow of superfluid helium through this miniature faucet does, indeed, appear to slow down.
"Our results suggest that a quantum faucet does show a fundamentally different behaviour," says McGill physics professor Guillaume Gervais, who led the project. "We don't have the smoking gun yet. But we think this a great step toward proving experimentally the Tomonaga-Luttinger theory in a real liquid."

The zone where physics changes

Insights from the research could someday contribute to novel technologies, such as nano-sensors with applications in GPS systems. But for now, Gervais says, the results are significant simply because "we're pushing the limit of understanding things on the nanoscale. We're approaching the grey zone where all physics changes."

Prof. Adrian Del Maestro from the University of Vermont has been employing high-performance computer simulations to understand just how small the faucet has to be before this new physics emerges. "The ability to study a quantum liquid at such diminutive length scales in the laboratory is extremely exciting as it allows us to extend our fundamental understanding of how atoms cooperate to form the superfluid state of matter," he says. "The superfluid slowdown we observe signals that this cooperation is starting to break down as the width of the pipe narrows to the nanoscale" and edges closer to the exotic one-dimensional limit envisioned in the Tomonaga-Luttinger theory.

Building what is probably the world's smallest faucet has been no simple task. Gervais hatched the idea during a five-minute conversation over coffee with a world-leading theoretical physicist. That was eight years ago. But getting the nano-plumbing to work took "at least 100 trials - maybe 200," says Gervais, who is a fellow of the Canadian Institute for Advanced Research..

A beam of electrons as drill bit

Using a beam of electrons as a kind of drill bit, the team made holes as small as seven nanometers wide in a piece of silicon nitride, a tough material used in applications such as automotive diesel engines and high-performance ball bearings. By cooling the apparatus to very low temperatures, placing superfluid helium on one side of the pore and applying a vacuum to the other, the researchers were able to observe the flow of the superfluid through the channel. Varying the size of the channel, they found that the maximum speed of the flow slowed as the radius of the pore decreased.

The experiments take advantage of a unique characteristic of superfluids. Unlike ordinary liquids - water or maple syrup, for example - superfluids can flow without any viscosity. As a result, they can course through extremely narrow channels; and once in motion, they don't need any pressure to keep going. Helium is the only element in nature known to become a superfluid; it does so when cooled to an extremely low temperature.

An inadvertent breakthrough

For years, however, the researchers were frustrated by a technical glitch: the tiny pore in the silicon nitride material kept getting clogged by contaminants. Then one day, while Gervais was away at a conference abroad, a new student in his lab inadvertently deviated from the team's operating procedure and left a valve open in the apparatus. "It turned out that this open valve kept the hole open," Gervais says. "It was the key to getting the experiment to work. Scientific breakthroughs don't always happen by design!"

Full bibliographic information

"Critical flow and dissipation in a quasi-one-dimensional superfluid," Pierre-François Duc, Michel Savard, Matei Petrescu, Bernd Rosenow, Adrian Del Maestro, Guillaume Gervais. Science Advances, published online May 15, 2015. 10.1126/sciadv.1400222


Prof. Bernd Rosenow, a quantum physicist at Leipzig University's Institute for Theoretical Physics, also contributed to the study.

Partners in research: This work was funded by the Natural Sciences and Engineering Research Council of Canada (NSERC), the Fonds de recherche du Québec - Nature et technologies (FRQNT), and the Canadian Institute for Advanced Research (CIFAR). Polytechnique Montréal provided access to a facility where the hole was made for the experiment. Computer simulations were performed at the Vermont Advanced Computing Core.

####

About McGill University
Founded in Montreal, Que., in 1821, is Canada’s leading post-secondary institution. It has two campuses, 11 faculties, 10 professional schools, 300 programs of study and more than 35,000 students. McGill attracts students from more than 150 countries around the world. Almost half of McGill students claim a first language other than English – including 6,000 francophones – with more than 6,800 international students making up almost 20 per cent of the student body.

Fondée à Montréal, au Québec, en 1821, l’Université McGill se classe comme chef de file parmi les universités canadiennes. McGill compte deux campus, 11 facultés, 10 écoles professionnelles, 300 programmes d’études et au-delà de 35 000 étudiants, originaires de 150 pays. L’Université accueille au-delà de 6 800 étudiants étrangers, qui composent près de 20 pour cent de sa population étudiante. Près de la moitié de ses étudiants ont une langue maternelle autre que l’anglais – dont 6 200 francophones.

For more information, please click here

Contacts:
Prof. Guillaume Gervais


Prof. Adrian Del Maestro


Chris Chipello
McGill University
514-398-4201


Joshua Brown
University of Vermont
802-656-3039

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