Smart material which responds to light stimulus can harness solar energy for applications in soft robotics

New Delhi :Scientists have developed a smart material which responds to light stimulus easily by converting light into thermal energy. This can be helpful for harnessing solar energy for applications in soft robotics and micro-electromechanical systems (MEMS) devices.

Many smart materials have successfully replicated stimuli-responsive behavior seen in abundance in nature like in Venus flytrap, pine cone, leaf of Mimosa pudica (‘touch me not’ plant), or a sunflower always trying to face the Sun. Venus flytrap closes its ciliated leaves when prey is in the vicinity. Liquid crystal polymer networks (LCNs) is one of such smart material. On application of heat, a uniformly aligned LCN film undergoes a reversible 2- or 3-dimensional shape change caused by the LC- liquid phase transition. By manipulating the average orientation of the rod-shaped LC molecules, various shape deformations like bending, curling, and even the formation of spiral ribbons have been attained in the past.

However, previously known devices needed additional layers to the photo-responding film to achieve bi-directional actuation—converting external energy to motion. As a solution to this problem, in a collaborative study, researchers at the Centre for Nano and Soft Matter Sciences (CeNS), Bengaluru, an autonomous institute of the Department of Science and Technology (DST), and the Department of Mechanical Engineering, IIT Madras, have fabricated spatially splay-deformed (spread out) LCN films, by crosslinking a mixture of mono-functional and bi-functional liquid crystal mesogens (a chemical compound). The two types of liquid crystal mesogens comprise one and two molecular units to absorb light, respectively, and incorporate near-infra-red (NIR)-active dye into the system. The NIR laser beam impinging on the film causes a significant rise in the local temperature, and the ensuing order-disorder transition leads to a change in the macroscopic shape or, in other words, thermo-mechanical actuation. The research has been published in the journal Soft Matter.

Dr. Divya Jayoti (currently at IIT Madras) and Prof. S. Krishna Prasad opined that large, fast, and bidirectional actuation could be achieved by carefully tuning the film’s geometric and material parameters. Dr. Ratna Kumar Annabattula and Mr. Akhil R. Peeketi at IIT Madras performed modelling and simulation of the thermal actuation. A further extension of the work demonstrated that the films also perform exceptionally well under solar stimulation, suggesting that they could be employed to harness solar energy for applications in soft robotics and MEMS devices.

Figure: (Top) Schematic representation of the experimental set-up to measure actuation: (a) NIR laser off and (b) NIR laser on. Snapshots of a 25 m  NIR LCN thin film in cantilever configuration at various time steps as seen in experiments (NIR intensity – 250 mW, middle panels) and finite element simulations (bottom panels).


Publication Details:  Divya Jayoti, Akhil Reddy Peeketi, Ratna Kumar Annabattula, and S. Krishna Prasad. “Dynamics of the photo-thermo-mechanical actuations in NIR-dye doped liquid crystal polymer networks.” Soft Matter (2022)

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