Professor Pradip K Maji and his team at Indian Institute of Technology Roorkee (IIT Roorkee), Department of Polymer and Process Engineering, have developed a structural colour-based sensors by making structural colour from an unexpected natural resource–agro-waste sugarcane bagasse. It is a structural colour-based stimulus-responsive sensor from Nano-cellulose having implications in intelligent packaging. The colour of the laminated films comes from a ‘chiral nematic liquid crystal,' a specific molecular self-assembly that interacts selectively with specific colours of visible light.
Professor Maji also emphasised that these sensing chips developed with an agro-waste-derived product show a dramatic change of reflection colour towards particular stimuli.
Today, colour trends in fashion and design include sparkling hues like holographic, pearlescent, and iridescent effects. Also, there is a cost to the environment. This development is a solution to the problem by using renewable resources like sugarcane bagasse. One of the important structural components obtained from sugarcane bagasse is cellulose.
Precisely, cellulose nanocrystal competes as the most relevant raw material to imitate natural structural-based colouration. Also, the nanocellulose suspension is non-toxic and produced from readily available natural material, and is highly suitable for upscaling. The bagasse must first be ground into tiny microscopic fragments called cellulose nanocrystals to make this structural colour film.
This process is divided into stages of bleaching raw fibre and acid hydrolysis of cellulose pulp under standardised conditions. The final CNC suspension is then concentrated to make it behave as a liquid crystal material showing amazing birefringence (splitting of light) properties. Ms Chhavi Verma, the lead author of the work, added that, as a team, they were marching ahead to their set goals of sustainability to make the structural colouration approach feasible and commercially available, thus reducing the use of chemically based dyes and pigments.
This is the first demonstration of a photonic film having the potential as a candidate material having implications in bio-optical engineering and intelligent packaging.