logo
ResearchBunny Logo
Abstract
Recent advances in thermally localized solar evaporation show promise for various applications, but salt accumulation is a major obstacle. This study demonstrates highly efficient (>80% solar-to-vapor conversion efficiency) and salt-rejecting (20 weight % salinity) solar evaporation using a wick-free confined water layer. Mechanistic modeling and experiments reveal that natural convection accelerates salt rejection with minimal heat loss. The approach is broadly applicable, improving efficiency when integrated with contactless solar evaporators. This work elucidates salt transport fundamentals and offers a low-cost strategy for high-performance solar evaporation.
Publisher
Nature Communications
Published On
Feb 14, 2022
Authors
Lenan Zhang, Xiangyu Li, Yang Zhong, Arny Leroy, Zhenyuan Xu, Lin Zhao, Evelyn N. Wang
Tags
solar evaporation
salt rejection
thermal efficiency
natural convection
mechanistic modeling
contactless evaporators

Related Publications

Explore these studies to deepen your understanding of the subject.

Highly efficient and robust noble-metal free bifunctional water electrolysis catalyst achieved via complementary charge transfer
Engineering and Technology

Highly efficient and robust noble-metal free bifunctional water electrolysis catalyst achieved via complementary charge transfer

N. K. Oh, J. Seo, et al.

A flexible pressure sensor with highly customizable sensitivity and linearity via positive design of microhierarchical structures with a hyperelastic model
Engineering and Technology

A flexible pressure sensor with highly customizable sensitivity and linearity via positive design of microhierarchical structures with a hyperelastic model

Z. Xu, D. Wu, et al.

Direct electrosynthesis and separation of ammonia and chlorine from waste streams via a stacked membrane-free electrolyzer
Engineering and Technology

Direct electrosynthesis and separation of ammonia and chlorine from waste streams via a stacked membrane-free electrolyzer

J. Gao, Q. Ma, et al.

Scalable and efficient solar-driven atmospheric water harvesting enabled by bidirectionally aligned and hierarchically structured nanocomposites
Engineering and Technology

Scalable and efficient solar-driven atmospheric water harvesting enabled by bidirectionally aligned and hierarchically structured nanocomposites

T. Li, T. Yan, et al.

Listen, Learn & Level Up
Over 10,000 hours of research content in 25+ fields, available in 12+ languages.
No more digging through PDFs—just hit play and absorb the world's latest research in your language, on your time.
listen to research audio papers with researchbunny