3D Printed Photoresponsive Devices Based on Shape Memory Composites

Compared with traditional stimuli-responsive devices with simple planar or tubular geometries, 3D printed stimuli-responsive devices not only intimately meet the requirement of complicated shapes at macrolevel but also satisfy various conformation changes triggered by external stimuli at the microscopic scale. However, their development is limited by the lack of 3D printing functional materials. This paper demonstrates the 3D printing of photoresponsive shape memory devices through combining fused deposition modeling printing technology and photoresponsive shape memory composites based on shape memory polymers and carbon black with high photothermal conversion efficiency. External illumination triggers the shape recovery of 3D printed devices from the temporary shape to the original shape. The effect of materials thickness and light density on the shape memory behavior of 3D printed devices is quantified and calculated. Remarkably, sunlight also triggers the shape memory behavior of these 3D printed devices. This facile printing strategy would provide tremendous opportunities for the design and fabrication of biomimetic smart devices and soft robotics.

3D printed photoresponsive devices are successfully fabricated through combining fused deposition modeling and photoresponsive shape memory composites based on polyurethane and carbon black. This study demonstrates the shape memory behavior of these 3D printed devices is well triggered by sunshine. This development provides tremendous opportunities for customized stimuli-responsive devices with complex geometry structure, which have potentials in soft robots, selectively pliable tools, and orthopedic surgery.

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