Nature-Inspired Polymeric Materials: Unveiling Unique Responsive Properties

Abstract

In nature, biological systems are able to respond autonomously to environmental cues. Drawing inspiration from nature, scientists have been creating materials that change their appearance, shape, or properties (e.g., optical or mechanical) in response to various stimuli. This work is our contribution to the field - we have designed a range of nature-inspired polymeric materials that reconfigure their properties in response to either physical cues (e.g., temperature) or chemicals in the external medium. In our initial study, our point of inspiration is the natural pearl, which displays a bright sheen (called ‘pearlescence’) due to light reflection from plate-like particles. We show, for the first time, that pearlescence can be reversibly induced in soft capsules that contain no plate-like particles. Our millimeter-sized capsules have an outer shell (~ 500 µm thick) of N-isopropylacrylamide (NIPA) gel, which shrinks above its lower critical solution temperature (LCST) of ~ 32°C. When a transparent capsule is heated above this LCST, it turns pearlescent, and the transparent state is recovered upon cooling. Specular reflectance measurements confirm that the pearlescence of the capsules is comparable to that of natural pearls. We attribute the pearlescence to light reflection from nanoscale domains in the shrunken NIPA shell above the LCST. Next, we draw inspiration from the skin of chameleons - the brilliant colors of the skin are due to ordered arrays (photonic crystals) of particles within the skin cells. To mimic this structure, we first create ‘photonic capsules’ with silica nanoparticles (NPs) in their liquid cores. When the capsules are placed in a polymer solution, the shell is impermeable to the polymer chains but is permeable to water. The resulting osmotic gradient induces the silica NPs to form close-packed arrays, i.e., photonic crystals, which deposit on the inner wall of the capsule. The capsules thereby show brilliant colors (iridescence), with the exact color depending on the NP size. We then further use these capsules as building blocks and fuse them together to form a free-standing sheet. The sheet is thus analogous to a tissue, with the capsules analogous to the constituent cells. We are thereby able to create a sheet of colored capsules, resembling the chameleon skin. Lastly, we take a step towards creating an ‘artificial muscle’. The muscles in our body are nature’s ideal machines as they can expand and contract at will. To mimic this ability, materials that change their size autonomously are of interest. With this goal in mind, we start with an anionic hydrogel with microscale pores - the gel expands by 300% when placed in water. When a carbodiimide is added to the water, it converts the carboxylates on the gel strands to anhydrides, and the loss of charge makes the gel shrink by 50%. The anhydrides are metastable, however, and hydrolyze over time - thereby, the charge on the chains is restored and the gel expands back to its initial size. A cycle of gel expansion and contraction is completed in ~ 40 min, which is ~ 10x faster than any previous soft autonomous material. The rapid response moves our gels closer to the timescales required for use in practical actuators or soft robots.