Affiliation:
1. Robert Frederick Smith School of Chemical and Biomolecular Engineering Cornell University 1 Ho Plaza Ithaca NY 14853 USA
2. Department of Chemical and Biological Engineering University of Wisconsin−Madison 1415 Engineering Drive Madison WI 53706 USA
3. Department of Chemistry and Biochemistry Kent State University 1175 Risman Drive Kent OH 44242 USA
Abstract
AbstractMicrotubules and catalytic motor proteins underlie the microscale actuation of living materials, and they have been used in reconstituted systems to harness chemical energy to drive new states of organization of soft matter (e.g., liquid crystals (LCs)). Such materials, however, are fragile and challenging to translate to technological contexts. Rapid (sub‐second) and reversible changes in the orientations of LCs at room temperature using reactions between gaseous hydrogen and oxygen that are catalyzed by Pd/Au surfaces are reported. Surface chemical analysis and computational chemistry studies confirm that dissociative adsorption of H2 on the Pd/Au films reduces preadsorbed O and generates 1 ML of adsorbed H, driving nitrile‐containing LCs from a perpendicular to a planar orientation. Subsequent exposure to O2 leads to oxidation of the adsorbed H, reformation of adsorbed O on the Pd/Au surface, and a return of the LC to its initial orientation. The roles of surface composition and reaction kinetics in determining the LC dynamics are described along with a proof‐of‐concept demonstration of microactuation of beads. These results provide fresh ideas for utilizing chemical energy and catalysis to reversibly actuate functional LCs on the microscale.
Funder
National Science Foundation
National Energy Research Scientific Computing Center
Office of Science