Traveling Wave Rotary Micromotor Based on a Photomechanical Response in Liquid Crystal Polymer Networks

Klaudia Dradrach; Mikołaj Rogóż; Przemysław Grabowski; Chen Xuan; Rafał Węgłowski; Jolanta Konieczkowska; Ewa Schab-Balcerzak; Wiktor Piecek; Piotr Wasylczyk

doi:10.1021/acsami.9b20309

Traveling Wave Rotary Micromotor Based on a Photomechanical Response in Liquid Crystal Polymer Networks

ACS Appl Mater Interfaces. 2020 Feb 19;12(7):8681-8686. doi: 10.1021/acsami.9b20309. Epub 2020 Feb 7.

Authors

Klaudia Dradrach¹, Mikołaj Rogóż¹, Przemysław Grabowski¹, Chen Xuan², Rafał Węgłowski³, Jolanta Konieczkowska⁴, Ewa Schab-Balcerzak⁴, Wiktor Piecek³, Piotr Wasylczyk¹

Affiliations

¹ Photonic Nanostructure Facility, Faculty of Physics , University of Warsaw , ul. Pasteura 5 , 02-093 , Warsaw , Poland.
² Department of Mathematical Sciences , Xi'an Jiaotong-Liverpool University , 111 Ren'ai Rd , Suzhou 215123 , China.
³ Institute of Applied Physics , Military University of Technology , ul. Kaliskiego 2 , 01-476 Warsaw , Poland.
⁴ Centre of Polymer and Carbon Materials , Polish Academy of Sciences , ul. M. Curie-Skłodowskiej 34 , 41-819 Zabrze , Poland.

Abstract

The photomechanical response of liquid crystal polymer networks (LCNs) can be used to directly convert light energy into different forms of mechanical energy. In this study, we demonstrate how a traveling deformation, induced in a liquid crystal polymer ring by a spatially modulated laser beam, can be used to drive the ring (the rotor) to rotate around a stationary element (the stator), thus forming a light-powered micromotor. The photomechanical response of the polymer film is modeled numerically, different LCN molecular configurations are studied, and the performance of a 5.5 mm diameter motor is characterized.

Keywords: light-powered mechanics; liquid crystal polymer networks; micromotor; photomechanic actuation; traveling wave motor.