Tailoring interfaces for atmospheric water harvesting: Fundamentals and applications

Water is the cradle of life, but the scarcity of freshwater imposed by the ever-increasing population and pollution threatens human sur-vival. Harvesting fresh water from the ubiquitous yet untapped at-mospheric water from the air, such as fog and vapor, presents a facile and powerful strategy to resolve the emerging water crisis. Over the past decades, diverse atmospheric water harvesting (AWH) technologies such as fog harvesting, dew collecting, and sor-bent-based vapor capture have been largely exploited, all of which rely on efficient regulation of water, heat, and energy transfer at the solid/liquid/air three-phase interface for boosting freshwater pro-duction. Therefore, fully understanding such sophisticated interfa-cial interactions will help to fundamentally improve the efficiency of AWH. In this review, we revisit the emerging progress of AWH technologies from the view of interfacial interactions among solid, liquid, and air. We then discuss how interfacial interactions deter-mine AWH performance by surface chemistry, topology structure, and optical, thermal, and electric properties. Finally, we highlight many AWH-enabling high-value-added practical applications, including energy generation, thermal and humidity management, and agriculture, as well as emphasize the unsolved contradictory challenges in the surface design of future AWH devices.

Automated summary

Water scarcity due to population growth and pollution poses a threat to human survival, but harvesting atmospheric water from fog and vapor can help resolve the emerging water crisis. In this review, we examine the progress of atmospheric water harvesting (AWH) technologies and discuss how interfacial interactions among solid, liquid, and air determine AWH performance. We also highlight practical applications of AWH and emphasize the challenges in the surface design of future AWH devices.