Light-powered swarming phoretic antimony chalcogenide-based microrobots with on-the-fly photodegradation abilities

Microrobots are at the forefront of research for biomedical and environmental applications. Whereas a single microrobot exhibits quite low performance in the large-scale environment, swarms of microrobots are representing a powerful tool in biomedical and environmental applications. Here, we fabricated phoretic Sb2S3-based microrobots that exhibited swarming behavior under light illumination without any addition of chemical fuel. The microrobots were prepared in an environmentally friendly way by reacting the precursors with bio-originated templates in aqueous solution in a microwave reactor. The crystalline Sb2S3 material provided the microrobots with interesting optical and semiconductive properties. Because of the formation of reactive oxygen species (ROS) upon light illumination, the microrobots possessed photocatalytic properties. To demonstrate the photocatalytic abilities, industrially used dyes, quinoline yellow and tartrazine were degraded using microrobots in the on-the-fly mode. Overall, this proof-of-concept work showed that Sb2S3 photoactive material is suitable for designing swarming microrobots for environmental remediation applications.

Automated summary

Microrobots, made from phoretic Sb2S3 material, demonstrated swarming behavior under light illumination without the need for chemical fuel. These environmentally friendly microrobots were prepared by reacting precursors with bio-originated templates in an aqueous solution in a microwave reactor. The photocatalytic abilities of the microrobots were showcased by degrading industrially used dyes, quinoline yellow and tartrazine, in the on-the-fly mode. This proof-of-concept work highlights the suitability of Sb2S3 photoactive material for designing swarming microrobots for environmental remediation applications.