Use C2021 Coupon To Save $10 - Valid till 30 November

Science | Unknown Liquid Phase Discovered in Glass Is ‘A New Type of Material’, Scientists Say


Science | Unknown Liquid Phase Discovered in Glass Is ‘A New Type of Material’, Scientists Say

SCIENCE | When different materials reach their ultimate limits, many strange things can happen – like the  recent discovery of a previously completely unknown liquid phase reported by scientists working on the development of super-thin, high-density glass.

These types of brand new glass are used in a vast variety of ways, including in normal OLED displays and optical fibers, but sometimes they can have many stability problems. It’s through an effort to completely tackle those problems that this different kind of material has come to light.

Crucially, the newly discovered liquid phase promises thin glass that’s more stable and denser than the materials that have come before – a progression that could open up different ways of using the glass, and even completely new types of devices.

“There are a lot of interesting properties that came out of nowhere, and nobody had thought that in thin films you would be able to see these phases,” says physicist Zahra Fakhraai from the University of Pennsylvania.

“It’s a new type of material.”

Glass is a very special type of material that typically forms as a liquid solidifies. While its properties become much like a solid, internally the structure of glass doesn’t change much from the liquid phase. It remains a fascinating transition for scientists.

In the case of ultra-thin glass, that transition can be hard to manage without running into problems like crystallization, especially at larger scales. Thin glasses retain more of their liquid properties than normal, which can lead to instability and degradation.

In other glasses, a technique known as vapor deposition – where a gas is turned into a solid directly – is used instead of cooling a liquid, but it hasn’t been clear whether this would help improve the stability of ultra-thin glasses.

In the new study, researchers spent years working on experiments to establish that vapor deposition would actually reduce some of the liquid-like properties of thin glass.

It was through this process, when dropping down to extremely cool temperatures, that the new phase of high-density supercooled liquid was spotted – one that differed from the liquid phase typically observed when producing ultra-thin glass.

“The two liquids have distinct structures, akin to graphene and diamond which are both solids made of carbon but exist in very different solid forms,” says Fakhraai.

Follow-up experiments confirmed the packing of individual molecules into a structure that wasn’t a crystal but something else. Based on the geometry of the phase, the researchers think there could be implications for other types of materials too.

What this means is the potential of producing ultra-thin glasses with a much higher density – higher than crystal in some cases – through vapor deposition and the new phase of liquid in glass.

Further studies are planned to establish exactly how this phase transition comes about, including a closer look at the deposition phase, and it could help scientists solve some of the other remaining mysteries of glass.

“Our hope is that this fundamental understanding motivates more applications and a better ability to design thin film glasses with similarly improved properties,” says Fakhraai. “If the structure-property relationships are understood in thin films, we can do better by design.”


Enhanced surface mobility enables rapid equilibration of vapor-deposited glasses toward the super-cooled liquid (SCL). PNAS demonstrates that thin films of N,N′-bis(3-methylphenyl)-N,N′-diphenylbenzidine molecular glass, when vapor deposited below a certain temperature, can access a high-density supercooled liquid (HD-SCL) state through a liquid–liquid phase transition ∼35 K below the nominal glass transition temperature of ordinary SCL.

The HD-SCL phase transforms into the ordinary SCL when the thickness is increased above 60 nm, demonstrating that HD-SCL is only thermodynamically favored in thin films. These results provide a recipe for accessing kinetically inaccessible regions in the energy landscape, which are critical for understanding the glass transition phenomenon. High-density stable glass states that can resist crystallization and dewetting is also important in various applications.


The finding results are published on PNAS  late  July 2021.




Leave your thought here

Your email address will not be published. Required fields are marked *

To apply for group training courses, please complete the form