A nature-inspired
water-cycling system, akin to trees, to perform
effective water and solar energy management for photosynthesis and
transpiration is considered to be a promising strategy to solve water
scarcity issues globally. However, challenges remain in terms of the
relatively low transport rate, short transport distance, and unsatisfactory
extraction efficiency. Herein, enlightened by conifer tracheid construction,
an efficient water transport and evaporation system composed of a
hierarchical structured aerogel is reported. This architecture with
radially aligned channels, micron pores, and molecular meshes is realized
by applying a radial ice-template method and in situ cryopolymerization technique. This nature-inspired design benefits
the aerogel excellent capillary rise performance, realizing a long-distance
(>28 cm at 190 min) and quick (>1 cm at 1 s, >9 cm at 300
s) antigravity
water transport on a macroscopic scale, regardless of clean water,
seawater, sandy groundwater, or dye-including effluent. Furthermore,
an efficient water transpiration and collection is performed by the
bilayer-structured aerogel with a carbon heat collector on an aerogel
top, demonstrating a solar steam generation rate of 2.0 kg m–2 h–1 with the energy conversion efficiency up to
85.7% under one solar illumination. This biomimetic design with the
advantage of water transport and evaporation provides a potential
approach to realize water purification, regeneration, and desalination.