'Twist and shine': Development of a new photoluminescent sensor material
OIST
Such light-based sensing molecules, also called photoluminescent mechanophores, are not new, but currently available applications are single-use only. They would typically involve a strong force -- compressing, twisting or stretching for example -- breaking a specific chemical bond between two atoms or irreversibly pulling apart two molecular patterns in the sensing molecule, changing the wavelength - and thus the color - of the light emitted by the mechanophore. Once these molecules have radically changed their structure in response to this force, it is extremely difficult to return to the initial situation. While these mechanophores are useful to understand the mechanical properties of an item or a material, they do not suit well for repeated exposure to mechanical stress.
To overcome this issue, Dr. Georgy Filonenko and Prof. Julia Khusnutdinova from the Coordination Chemistry and Catalysis Unit designed a photoluminescent mechanophore that retains its properties over time and under repeated incidences of mechanical stress. The researchers incorporated the stress-sensing molecule into a common polymer material called polyurethane, widely used for everyday items from mattresses and cushions to inflatable boats, car interiors, woodworking glue and even spandex.
The scientists then stretched the resulting material with increasing force, triggering a correspondingly brighter glow under an ultraviolet light. The reaction happens within hundreds of milliseconds, resulting in a up to two-fold increase in luminescence intensity. When the mechanical traction stops, the polymer material and the mechanophore reverse to their initial position, decreasing the light readout. This is critical as it allows for repeated applications of mechanical force.
This new mechanophore is a photoluminescent compound from recently published work by Dr. Filonenko and Prof. Khusnutdinova. Despite its very simple structure the compound is extremely responsive to the physical environment which has a direct impact on the color visible with the naked eye under a UV light. These molecules were incorporated directly within the repeated patterns of the polymer material.
The high mobility of the mechanophore molecules in the polymer was found to be the key to the sensor performance. As mechanophores moved rapidly in the relaxed polymer sample, the brightness of emission was low due to these molecular motions preventing the mechanophore from emitting light. However, subjecting the material to mechanical force effectively slowed down the polymer chain motions, enabling the mechanophore to emit light more efficiently.
"Our material shows how a macroscopic force, as basic as stretching a flexible strand of material, can efficiently trigger microscopic changes all the way down to isolated molecules," commented Dr. Filonenko.
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