Liquid Crystal Elastomer Actuators Enhanced by Tapered Optical Fibers for Controllable Bending Directions and Amplitudes

Abstract Liquid crystal elastomer (LCE) photoactuators offer a versatile platform for executing complicated tasks through precisely controlled bending directions and amplitudes. Optical waveguides assist photoactuators to perform tasks unimpededly. While most existing optical waveguide actuators are limited to unidirectional bending, limiting their versatility. Here, a LCE actuator integrated with a tapered optical fiber with controllable bending directions and amplitudes is presented. The LCE actuator displays bending motions induced by uneven shrinkage due to the off‐center fiber. The bending directions are parallel to the previous uniaxial alignment of the LCE film, which can be adjusted to an arbitrary angle with the tapered optical fiber. The LCE actuators exhibit adaptable bending directions at 0°, 45°, and 90°, representing the possible bending motions. The bending amplitudes are regulated by infrared laser power. A hook‐like LCE actuator with 0° bending direction carried the handle of a basket. In addition, a 90° bending direction LCE actuator displays the shrinkage behavior, showing a special bending motion control. Moreover, a bionic hand, comprising five LCE actuators with various bending directions, exhibited diverse gestures with precise control. The controllable bending motions in optical waveguide actuators expand the promising applications in complicated scenarios, such as catheters or other medical devices.