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Mechanochromic, Structurally Colored, and Edible Hydrogels Prepared from Hydroxypropyl Cellulose and Gelatin
Abstract: Hydroxypropyl cellulose (HPC) is an edible, costâeffective and widely used derivative of cellulose. Under lyotropic conditions in water, HPC forms a photonic, liquid crystalline mesophase with an exceptional mechanochromic response. However, due to insufficient physical crossâlinking photonic HPC can flow freely as a viscous liquid, preventing the exploitation of this mechanochromic material in the absence of any external encapsulation or structural confinement. Here this challenge is addressed by mixing HPC and gelatin in water to form a selfâsupporting, viscoelastic, and edible supramolecular photonic hydrogel. It is demonstrated that the structural coloration, mechanochromism and nonâNewtonian shearâthinning behavior of the lyotropic HPC solutions can all be retained into the gel state. Moreover, the rigidity of the HPCâgel provides a 69% shorter mechanochromic relaxation time back to its initial color when compared to the liquid HPCâwater only system, broadening the dynamic color range of HPC by approximately 2.5Ă in response to a compressive pressure. Finally, the ability to formulate the HPCâgels in a scalable fashion from only water and âfoodâgradeâ constituents unlocks a wide range of potential applications, from responseâtunable mechanochromic materials and colorantâfree food decoration, to shortâterm sensors in, for example, biodegradable âsmart labelsâ for food packaging
Roll-to-roll fabrication of touch-responsive cellulose photonic laminates.
Hydroxypropyl-cellulose (HPC), a derivative of naturally abundant cellulose, can self-assemble into helical nanostructures that lead to striking colouration from Bragg reflections. The helical periodicity is very sensitive to pressure, rendering HPC a responsive photonic material. Recent advances in elucidating these HPC mechano-chromic properties have so-far delivered few real-world applications, which require both up-scaling fabrication and digital translation of their colour changes. Here we present roll-to-roll manufactured metre-scale HPC laminates using continuous coating and encapsulation. We quantify the pressure response of the encapsulated HPC using optical analyses of the pressure-induced hue change as perceived by the human eye and digital imaging. Finally, we show the ability to capture real-time pressure distributions and temporal evolution of a human foot-print on our HPC laminates. This is the first demonstration of a large area and cost-effective method for fabricating HPC stimuli-responsive photonic films, which can generate pressure maps that can be read out with standard cameras