A study led by researchers at the BIST centre ICN2 and recently published in Nature Physics provides new insights into the glass to supercooled-liquid transition, a complex phenomenon that still holds many secrets. A new mechanism that drives the transition under specific conditions is introduced. These results will spark further research and enable novel and improved applications, in particular in the field of organic electronics.
Glasses are peculiar materials exhibiting excellent and well-known properties, but also some phenomena that are still not fully understood, even though they have been studied for more than a century. In particular, researchers have not yet reached a complete description of the glass formation process, upon cooling a liquid, and the converse transition of glass to a more stable state –called supercooled liquid— when it is heated up. A study recently published in Nature Physics, led by members of the ICN2 Thermal Properties of Nanoscale Materials Group, sheds new light on this conundrum.
A glass is an amorphous solid, a state of matter characterised by the absence of a long-range order. In other words, it does not have a crystalline structure like a ‘regular’ solid, but its molecules cannot move as in a liquid either due to very high viscosity. Since this state is not energetically stable, atoms or molecules in glasses tend to rearrange themselves over time, leading towards more stable configurations. Such a reconfiguring process, which occurs naturally, is facilitated by an increase in temperature. When a glass is heated up to its specific transition temperature, its components acquire additional mobility, and the material becomes a supercooled liquid.
Conventionally, this transition from glass to liquid is described as a dynamic process in which atoms or molecules go through a cooperative relaxation. This means that regions of the glass having slightly higher mobility induce adjacent zones to progressively transit to a liquid state and reach an equilibrium phase. According to this theory, the increase of mobility is gradual, and the relaxation takes place in the whole material in a cooperative and almost uniform fashion. But is it always so?
The abovementioned study led by Prof Javier Rodriguez-Viejo and Dr Marta Gonzalez-Silveira – group leader and senior researcher, respectively, in the ICN2 Thermal Properties of Nanoscale Materials Group and at the Universitat Autònoma de Barcelona (UAB)— provides a more precise description of this phenomenon. The researchers demonstrated experimentally that, under specific conditions, the transition from glass to supercooled liquid can originate from a rapid formation of localised liquid regions, whose mobility is much higher than that of the rest of the material and which expand quickly.
This results in a stage where parts of the material are already in a stable liquid phase, while others are still glassy, something that does not occur with cooperative relaxation. For these two states to coexist in localised regions, the difference in mobility between the liquid and the glass parts must be very significant.
The authors demonstrated that both these mechanisms —i.e., the formation of expanding liquid regions and the cooperative relaxation— can take place when the glass is heated up, depending on the conditions of the process. Which of the two prevails is dictated by the specific temperature of the glass but does not depend on the procedure used to form the original glass or on its initial stability.
This study –whose co-authors are Ana Vila-Costa, Dr Cristian Rodríguez-Tinoco and Marta Rodríguez-López— was made possible by the use of advanced laboratory techniques, such as nanocalorimetry, which allows observing glass dynamics at the nanoscale and performing measurements at temperature ranges and time scales that cannot be achieved by conventional methods. These results add new important pieces to the description of the complex glass-liquid transition process and open the way to new theories and in-depth studies.
A deeper understanding of the physics of glass will enable its properties to be exploited for new or improved applications. In particular, this exotic transformation mechanism is behind the very high stability of vapor-deposited ultrastable glasses, including the organic ones, and may therefore have a positive impact on the durability of organic devices or the production of metallic glasses with enhanced mechanical properties for wear- and corrosion-resistant coatings.
Ana Vila-Costa, Marta Gonzalez-Silveira, Cristian Rodríguez-Tinoco, Marta Rodríguez-López & Javier Rodriguez-Viejo, Emergence of equilibrated liquid regions within the glass. Nat. Phys. (2022). DOI: 10.1038/s41567-022-01791-w
Learn more on the ICN2 website.