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Size-Insensitive Vapor Diffusion Enabled by Additive Freeze-Printed Aerogels for Scalable Desalination

Xiaomeng Zhao, Yunfei Yang, Xuemin Yin, Zhuo Luo, Kim Young Chan, Xi Shen

2025ACS Energy Letters12 citationsDOI

Abstract

Porous materials are widely used as photothermal evaporators for solar-powered desalination. However, conventional evaporators suffer a significant performance decline as size increases, limiting the scalability from laboratory to practical scales. This work addresses the fundamental limitation behind the size–performance trade-off through modeling-guided design and additive manufacturing. A coupled heat and vapor transport model reveals that vapor diffusion resistance increases with evaporator size due to thickened boundary layers. A hierarchical porous aerogel fabricated by using an additive freeze-printing technique decouples the boundary layer thickness from overall device dimension, achieving size-insensitive vapor diffusion. Unlike conventional evaporators that suffer over 40% reduction in evaporation performance with increasing size, the resulting aerogel maintains an evaporation rate above 2 kg m –2 h –1 and energy efficiency over 80%, with less than 5% reduction. Our findings provide new insights into the vapor diffusion mechanism in porous evaporators and offer a practical solution for scalable solar-driven desalination.

Topics & Concepts

Materials scienceDesalinationDiffusionNanotechnologyChemical engineeringChemistryMembraneEngineeringThermodynamicsBiochemistryPhysicsSolar-Powered Water Purification MethodsMembrane Separation TechnologiesAdsorption and Cooling Systems
Size-Insensitive Vapor Diffusion Enabled by Additive Freeze-Printed Aerogels for Scalable Desalination | Litcius