The glass transition caught in the act

Islands of cooperating atoms jam like ice floes as a liquid becomes like glass

Glasses form when a liquid is cooled so rapidly its atoms or molecules don't have time to find their places in the regular pattern that characterizes crystalline solids.

We learn in school that matter comes in three states: solid, liquid and gas. A bored and clever student (we’ve all met one) then sometimes asks whether glass is a solid or a liquid.

The student has a point. Glasses are weird “solid liquids” that are cooled so fast their atoms or molecules jammed before organizing themselves in the regular patterns of a crystalline solid. So a glass has the mechanical properties of a solid, but its atoms or molecules are disorganized, like those in a liquid.

One sign of the weirdness of glass is that the transition from liquid to a glass is much fuzzier than the transition from liquid to crystalline solid. In fact, the glass transition is arbitrarily defined as the point where the glass-forming material has a viscosity of 1013 poise. (The viscosity of water at room temperature is about 0.01 poise.  A thick oil might have a viscosity of about 1.0 poise.) At this point, it is too thick to flow and so meets the practical definition of a solid.

Scientists hate definitions this vague, but they’ve been stuck with this one because nobody really understood the glass transition, which frequently makes it onto lists of the top-10 unsolved problems in physics.

For the most part, scientists have been able to measure only bulk properties of glass-forming liquids, such as viscosity and specific heat, and the interpretations they came up with depended in part on the measurements they took. The glass literature is notoriously full of contradictory findings and workshops about glass are the venue for lively debate.

But in the past 15 years, new experimental setups that scatter X-rays or neutrons off the atoms in a droplet of liquid that is held without a container (which would provoke it to crystallize) have allowed scientists at long last to measure the atomic properties of the liquid. And that is the level at which they suspect the secrets of the glass transition are hidden.

In one such study, Ken Kelton, the Arthur Holly Compton Professor in Arts & Sciences at Washington University in St. Louis, and  his research team (Chris Pueblo, of Washington University, and Minhua Sun, of Harbin Normal University in China) compared a measure of the interaction of atoms for different glass-forming liquids. Their results, published online in Nature Materials, reconcile several measures of glass formation, a sign that they are on the right track.

Glasses, glasses, everywhere

Ken Kelton has pursued the glass transition for many years both because the physics are interesting and, he confesses, because he just plain likes liquids and glasses. But when he Googles people who have cited his papers, he often finds they work in industry. This is because glasses are everywhere. Most of us think of glass as window glass or drinking glasses, but many foodstuffs, drugs and plastics are also glasses.

Dry spaghetti is hard and brittle because it is a glass. When it is heated in boiling water it undergoes a transition to a “rubbery” state that goes well with red sauce. Cotton candy is a glass made by melting sugar crystals and then spinning out the melt so that strands of molten sugar “freeze” in the form of a glass. Cheetos, prawn crackers and dry milk powder are all glasses, as are many other foods.

Pharmaceutical companies often use spray-drying or freeze-drying to make sure a drug is glassy rather than crystalline. Many hard plastics, such as polysytrene (packing peanuts, disposable razors) and polyvinyl chloride (vinyl siding, plumbing) are also glasses.

Industrial scientists are scanning Kelton’s papers because they need to control the glass transition and the transformation of the glass to a crystalline solid in order to give their products desirable properties. Drugs in a glassy state generally dissolve better in the body, so that lower doses are effective, and some drugs must be produced as glasses because they are insoluble in their crystalline form. Control of the glass transition is also important in the production of plastics. Because they are glasses, hard plastics have a “memory” of their thermal history that affects how they perform and age.

“We have shown that the concept of fragile and strong liquids, which was invented to explain why viscosity changes in markedly different ways as a liquid cools, actually goes much deeper than just the viscosity,” Kelton said. “It is ultimately related to the repulsion between atoms, which limits their ability to move cooperatively. This is why the distinction between fragile and strong liquids also appears in structural properties, elastic properties and dynamics. They’re all just different manifestations of that atomic interaction.”

This is the first time the connection between viscosity and atomic interactions has been demonstrated experimentally, he said. Intriguingly, his studies and work by others suggest that the glass transition begins not at the conventional glass transition temperature but rather at a temperature approximately two times higher in metallic  glasses (more than two times higher in the silicate glasses, such as window glass). It is at that point, Kelton said, the atoms first begin to move cooperatively.

Drilling down to the atomic level

Kelton’s latest discoveries follow earlier investigations of a characteristic of glass-forming liquids called fragility. To most people, all glasses are fragile, but to physicists some are “strong” and others are “fragile.”

The distinction was first introduced in 1995 by Austen Angell, a professor of chemistry at Arizona State University, who felt that a new term was needed to capture dramatic differences in the way a liquid’s viscosity increases as it approaches the glass transition.

The viscosities of some liquids change gradually and smoothly as they approach this transition. But as other liquids are cooled, their viscosity changes very little at first, but then takes off like a rocket as the transition temperature approaches.

At the time, Angell could only measure viscosity, but he called the first type of liquid “strong” and the second type “fragile” because he suspected a structural difference underlay the differences that he saw.

“It’s easier to explain what he meant if you think of a glass becoming a liquid rather than the other way around,” Kelton said. “Suppose a glass is heated through the glass transition temperature. If it’s a ‘strong’ system, it ‘remembers’ the structure it had as a glass—which is more ordered than in a liquid—and that tells you that the structure does not change much through the transition. In contrast, a ‘fragile’ system quickly ‘forgets’ its glass structure, which tells you that its structure changes a lot through the transition.

“People argued that the change in viscosity had to be related to the structure — through several intermediate concepts, some of which are not well defined,” Kelton added. “What we did was hop over these intermediate steps to show directly that fragility was related to structure.”

In 2014, he with members of his group published in Nature Communications the results of experiments that showed that the fragility of a glass-forming liquid is reflected in something called the structure factor, a quantity measured by scattering X-rays off a droplet of liquid that contains information about the position of the atoms in the droplet.

“It was just as Angell had suspected,” Kelton said. “The rate of atomic ordering in the liquid near the transition temperature determines whether a liquid is ‘fragile’ or ‘strong.'”

Sharp little atomic elbows

But Kelton wasn’t satisfied. Other scientists were finding correlations between the fragility of a liquid and its elastic properties and dynamics, as well as its structure. “There has to be something in common,” he thought. “What’s the one thing that could underlie all of these things?” The answer, he believed, had to be the changing attraction and repulsion between atoms as they moved closer together, which is called the atomic interaction potential.

If two atoms are well separated, Kelton explained, there is little interaction between them and the interatomic potential is nearly zero. When they get closer together, they are attracted to one another for a variety of reasons. The potential energy goes down, becoming negative (or attractive). But then as they move closer still, the cores of the atoms start to interact, repelling one another. The energy shoots way up.

“It’s that repulsive part of the potential we were seeing in our experiments,” Kelton said.

What they found when they measured the repulsive potential of 10 different metallic alloys at the Advanced Photon Source, a beamline at Argonne National Laboratory, is that “strong” liquids have steeper repulsive potentials and the slope of their repulsive potential changes more rapidly that of “fragile” ones.

“What this means,” Kelton said, “is that ‘strong’ liquids order more rapidly at high temperatures than ‘fragile’ ones. That is the microscopic underpinning of Angell’s fragility.

A levitated drop of a metallic liquid inside an instrument used to study the glass transition. Electrodes above and below the sample charge its surface by induction, and it rises in the evacuated chamber, hoisted by electrostatic attraction. The sample is melted by laser and then bombarded by an intense beam of X-rays produced by a synchrotron. The pattern in which the X-rays scatter contains information about the positions and interactions of the atoms in the droplet. (Image: Ken Kelton)

“What’s interesting,” Kelton continued, “is that we see atoms beginning to respond cooperatively — showing awareness of one another — at temperatures approximately double the glass transition temperature and close to the melting temperature.

“That’s where the glass transition really starts,” he said. “As the liquid cools more and more,  atoms move cooperatively until rafts of cooperation extend from one side of the liquid to the other and the atoms jam. But that point, the conventional glass transition, is only the end point of a continuous process that begins at a much higher temperature.”

Kelton will soon attend a workshop in Poland where he expects lively discussion of his findings, which contradict those of some of his colleagues. But he is convinced that he has hold of the thread that will lead out of the labyrinth because different levels of understanding are beginning to line up. “It’s exciting that things are coming together so well,” he said.

 

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