Optically addressable dielectric elastomer actuator arrays using embedded percolative networks of zinc oxide nanowires

Dielectric elastomer actuators (DEAs) are electrically driven soft actuators that generate fast and reversible deformations, enabling lightweight actuation of many novel soft robots and haptic devices. However, the high-voltage operation of DEAs combined with the paucity of soft, small high-voltage microelectronics has limited the number of discrete DEAs that can be incorporated into soft robots. This has hindered the versatility as well as complexity of the tasks that they can perform which, in practice, depends on the number of independently addressable actuating elements. This paper presents a new class of optically addressable dielectric elastomer actuators that utilize the photoconductivity of semiconducting zinc oxide nanowires to create optically switchable and stretchable electrical channels. This enables non-contact, optical control of local actuation. To illustrate the versatility of the new capabilities of this integration, we describe the response of dielectric elastomer actuators with integrated photoconductive channels, formed from thin films of percolating semiconducting nanoparticles. By using a switchable array of small light emitting diodes to optically address the actuator array, its actuation can be controlled both spatially and temporally.

Automated summary

Dielectric elastomer actuators (DEAs) are soft actuators that can generate fast and reversible deformations for soft robots and haptic devices. However, the limited availability of high-voltage microelectronics has restricted the number of DEAs that can be incorporated into soft robots. This paper presents a new class of optically addressable DEAs that use photoconductivity to create optically switchable and stretchable electrical channels, enabling non-contact, optical control of local actuation.