Photodeformable Liquid Crystalline Polymers Containing Functional Additives: Toward Photomanipulatable Intelligent Soft Systems

Y Deformable liquid crystalline polymers (LCPs) have been an attractive topic for years because of their great potential in intelligent soft systems such as artificial muscles, soft robotics, and smart optical devices. However, the application of conventional thermal-responsive LCPs is usually limited by the low thermal conductivity of the polymer matrix and the high dependency on external heating device. In comparison, light-controlled methods have many advantages, including being noncontact, remote in situ, and the ability to manipulate the spatial resolution of LCPs, which facilitate the development of diverse untethered and remotely manipulatable intelligent soft devices. Recently, remarkable progress has been made in the development of photodeformable LCPs by incorporation of organic or/and inorganic photoresponsive components as functional additives because the diverse functions of the incorporated components can be facilely combined with the directional shape-morphing behaviors of LCPs in these systems via the interplay among the functional building blocks, mesomorphic phases, and polymer matrices. This review focuses on the design strategies, manufacturing methods, and working principles of photomanipulatable LCPs with incorporated photosensitive organic dyes or/and inorganic nanocomponents. Their possible applications and future developments are also briefly summarized.

Automated summary

Deformable liquid crystalline polymers (LCPs) have been a popular topic of research for years, with recent focus on light-controlled methods for their application. Photodeformable LCPs, incorporating organic or inorganic photoresponsive components as additives, have shown significant progress in combining diverse functions with shape-morphing behaviors. These advancements have the potential to facilitate the development of various untethered and remotely operable intelligent soft devices.