Dynamic structures that respond reversibly to changes in their environment are central to self-regulating thermal and lighting systems, targeted drug delivery, sensors and self-propelled locomotion. Since an adaptive change requires energy input, an ideal strategy would be to design materials that harvest energy directly from the environment and use it to drive an appropriate response. New synthetic approaches that would lead to such adaptive materials present a real challenge for materials chemistry in the 21st century.

To address this challenge, Aizenberg will describe the design of a novel class of reconfigurable materials that, similar to skeletomuscular systems, use a hybrid architecture to interconvert energy between different forms and scales. To specify the materials’ functions, Aizenberg’s research group uses surfaces bearing arrays of nanostructures put in motion by environment-responsive gels.

Their unique topography can be designed to confer a wide range of adaptive optical, wetting, adhesive, anti-bacterial, motion-generating, and other behaviors, similar to their natural counterparts used by lotus leaves to shed water, geckos to stick to surfaces, cephalopods to change color, echinoderms to keep their skin clean and fish to sense flow.

Using both experimental and modeling approaches as well as new fabrication methods, Aizenberg’s group is developing the ability to take full advantage of the immense potential for energy coupling within these hybrids to create a generation of sustainable, self-reporting, self-adapting materials.

Biography:
Joanna Aizenberg is the Amy Smith Berylson professor of materials science; professor of chemistry and chemical biology, Radcliffe Professor and the Director of the Kavli Institute for Bionano Science and Technology at Harvard University.