Photo-actuators via epitaxial growth of microcrystal arrays in polymer membranes

Photomechanical crystals composed of three-dimensionally ordered and densely packed photochromes hold promise for high-performance photochemical actuators. However, bulk crystals with high structural ordering are severely limited in their flexibility, resulting in poor processibility and a tendency to fragment upon light exposure, while previous nano- or microcrystalline composites have lacked global alignment. Here we demonstrate a photon-fuelled macroscopic actuator consisting of diarylethene microcrystals in a polyethylene terephthalate host matrix. These microcrystals survive large deformations and show a high degree of three-dimensional ordering dictated by the anisotropic polyethylene terephthalate, which critically also has a similar stiffness. Overall, these ordered and compliant composites exhibit rapid response times, sustain a performance of over at least hundreds of cycles and generate work densities exceeding those of single crystals. Our composites represent the state-of-the-art for photochemical actuators and enable properties unattainable by single crystals, such as controllable, reversible and abrupt jumping (photosalient behaviour). Photomechanical crystals are promising materials for converting photon energy into macroscopic work via reversible structural changes when exposed to light. Here the authors demonstrate highly ordered and compliant microcrystalline composites with a photomechanical performance exceeding that of single crystals.

Automated summary

By incorporating diarylethene microcrystals into a polyethylene terephthalate matrix, highly ordered and compliant photomechanical composites with superior performance compared to single crystals are achieved. These composites exhibit rapid response times, sustain a high level of performance over numerous cycles, and generate high work densities.