Chameleon-inspired structural color soft actuators interact with the environment. Courtesy of professor Xuemin Du.
The robot’s instant and reversible color change results from the absorption or desorption of vapors into or from inverse opal films, which the researchers fabricated by using highly ordered silica colloidal crystals as structural templates. The exhibited colors can be tuned by varying the assembled particle size of the inverse opals or by changing the concentration of the driving vapors.
Various controllable shape transformations, including tube-curling, twisting, and rolling shapes, can be integrated to form an adaptive actuation system with synchronous changes in its shape and colors. Compared with other soft coloractuators, the structural color actuator exhibits extremely rapid response (less than 1 s for color alteration and shape deformation) and robust actuation stabilities (greater than 110 cycles without obvious fatigue), the researchers said.
The researchers believe that various smart actuation systems with well-coordinated color and shape alteration could be developed by integrating intelligent functions, such as self-healing or self-adaptive capabilities, into the materials. By modifying the actuators to become aware of other stimuli, such as pressure, thermal, light, electric fields, and magnetic fields, many different types of robots that sense, respond, and interact with the environment could be created.
The research was published in Matter (https://doi.org/10.1016/j.matt.2019.05.012).
A closing/blooming flower with vivid color changes. Courtesy of professor Xuemin Du.