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Light‐Powered Autonomous Flagella‐Like Motion of Molecular Crystal Microwires

Fei Tong, Daichi Kitagawa, Ibraheem Bushnak, Rabih O. Al‐Kaysi, Christopher J. Bardeen

2020Angewandte Chemie22 citationsDOI

Abstract

Abstract The ability to exhibit life‐like oscillatory motion fueled by light represents a new capability for stimuli‐responsive materials. Although this capability has been demonstrated in soft materials like polymers, it has never been observed in molecular crystals, which are not generally regarded as dynamic objects. In this work, it is shown that molecular crystalline microwires composed of (Z)‐2‐(3‐(anthracen‐9‐yl)allylidene)malononitrile ((Z)‐ DVAM ) can be continuously actuated when exposed to a combination of ultraviolet and visible light. The photo‐induced motion mimics the oscillatory behavior of biological flagella and enables propagation of microwires across a surface and through liquids, with translational speeds up to 7 μm s −1 . This is the first example of molecular crystals that show complex oscillatory behavior under continuous irradiation. A model that relates the rotation of the transition dipole moment between reversible E→Z photoisomerization to the microscopic torque can qualitatively reproduce how the rotational frequency depends on light intensity and polarization.

Topics & Concepts

PhotoisomerizationMaterials scienceRotation around a fixed axisDipoleChemical physicsPolarization (electrochemistry)Liquid crystalTorqueTranslational motionRotation (mathematics)Molecular dynamicsPolymerOpticsOptoelectronicsMolecular physicsPhysicsChemistryClassical mechanicsComputational chemistryPhysical chemistryComposite materialThermodynamicsBiochemistryGeometryQuantum mechanicsIsomerizationMathematicsCatalysisAdvanced Materials and MechanicsLiquid Crystal Research AdvancementsPhotochromic and Fluorescence Chemistry