Spontaneous Directional Self‐Cleaning on the Feathers of the Aquatic Bird Anser cygnoides domesticus Induced by a Transient Superhydrophilicity

In nature, the feathers of the goose Anser cygnoides domesticus stay superhydrophobic over a long term, thought as the main reason for keeping the surface clean. However, contaminants, especially those that are oleophilic or trapped within textures, cannot be removed off the superhydrophobic feathers spontaneously. Here, a different self‐cleaning strategy based on superhydrophilic feathers is revealed that is imparted by self‐coating of the amphiphilic saliva, which enables removing away low‐surface‐tension and/or small‐size contaminants by forming directional water sheeting depending on their unique anisotropic microstructures. Particularly, the surface superhydrophilicity is switchable to superhydrophobicity upon exposure to air for maintaining a clean surface for a long time, which is further enhanced by coating with self‐secreted preening oil. By alternate switching between a transient superhydrophilicity and a long‐term stable superhydrophobicity, the goose feathers exhibit an integrated smart self‐cleaning strategy, which is also shared by other aquatic birds. An attractive point is the re‐entrant structure of the feathers, which facilitates not only liquid spreading on superhydrophilic feathers, but also long‐term stability of the cleaned surface by shedding water droplets off the superhydrophobicity feathers. Thus, artificial self‐cleaning microtextures are developed. The result renews the common knowledge on the self‐cleaning of aquatic bird feathers, offering inspiration for developing bioinspired self‐cleaning microtextures and coatings. Directional self‐cleaning on goose feathers induced by a transient surface superhydrophilicity is revealed, which enables removing away both low‐surface‐tension and small size contaminants in a preferred direction depending on the anisotropic surface microstructures. The superhydrophilicity‐induced directional self‐cleaning represents a very different self‐cleaning strategy from that aroused by the superhydrophobic feathers.