A dual-biomimetic knitted fabric with a manipulable structure and wettability for highly efficient fog harvesting

A dual-biomimetic knitted fabric with a manipulable structure and wettability for highly efficient fog harvesting

The shortage of freshwater severely constrains economic development and social security worldwide. Bio-inspired functional fog-harvesting devices (FHDs) have been broadly exploited to tackle this global challenge. Despite the great advances achieved in FHDs, efficient and large-scale water harvestin...

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Veröffentlicht in:Journal of materials chemistry. A, Materials for energy and sustainability Materials for energy and sustainability, 2021-12, Vol.1 (1), p.34-312
Hauptverfasser: Yu, Zhihua, Li, Shuhui, Liu, Mingming, Zhu, Ruofei, Yu, Mengnan, Dong, Xiuli, Sun, Yaxin, Fu, Shaohai
Format: Artikel
Sprache:eng
Schlagworte:
Biomimetics
Durability
Economic development
Fabrics
Fog
Hydrophobicity
Knitting
Low cost
Mechanical properties
Social security
Technology
Water harvesting
Water transportation
Wettability
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container_issue 1
container_start_page 34
container_title Journal of materials chemistry. A, Materials for energy and sustainability
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creator Yu, Zhihua
Li, Shuhui
Liu, Mingming
Zhu, Ruofei
Yu, Mengnan
Dong, Xiuli
Sun, Yaxin
Fu, Shaohai
description The shortage of freshwater severely constrains economic development and social security worldwide. Bio-inspired functional fog-harvesting devices (FHDs) have been broadly exploited to tackle this global challenge. Despite the great advances achieved in FHDs, efficient and large-scale water harvesting is still hindered by some inherent limitations: (1) a rational structure should be designed to maximize the function of the separated hydrophilic and hydrophobic regions, (2) simple, low-cost and mature manufacturing technology can better realize the large-scale production of FHDs. Here, inspired by the unique wettability of Namib desert beetles and the wedge-shaped structure of leaf veins, we prepared a dual-biomimetic tuck fabric with a manipulable structure and wettability using knitting technology, which greatly enhanced the fog capture velocity and directional water transportation. The influences of different structures and wettability on fog capture and droplet transportation efficiency have been systematically investigated. Moreover, massive theoretical models were proposed to reveal the fog harvesting mechanism. The optimized FHD exhibited rapid and highly efficient fog harvesting capacity (5424 mg h −1 cm −2 ). In addition, the prepared FHD showed excellent mechanical strength and durability, enabling low-cost and large-scale production. Thus, this work reinforces the understanding of the fundamental research and significantly promotes the practical applications of functional fog-harvesting devices. A bio-inspired fabric with wedge-shaped tracks and patterned wettability was fabricated using knitting technology. The dual-biomimetic knitted fabric exhibited excellent fog harvesting performance.
doi_str_mv 10.1039/d1ta08295g
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Bio-inspired functional fog-harvesting devices (FHDs) have been broadly exploited to tackle this global challenge. Despite the great advances achieved in FHDs, efficient and large-scale water harvesting is still hindered by some inherent limitations: (1) a rational structure should be designed to maximize the function of the separated hydrophilic and hydrophobic regions, (2) simple, low-cost and mature manufacturing technology can better realize the large-scale production of FHDs. Here, inspired by the unique wettability of Namib desert beetles and the wedge-shaped structure of leaf veins, we prepared a dual-biomimetic tuck fabric with a manipulable structure and wettability using knitting technology, which greatly enhanced the fog capture velocity and directional water transportation. The influences of different structures and wettability on fog capture and droplet transportation efficiency have been systematically investigated. Moreover, massive theoretical models were proposed to reveal the fog harvesting mechanism. The optimized FHD exhibited rapid and highly efficient fog harvesting capacity (5424 mg h −1 cm −2 ). In addition, the prepared FHD showed excellent mechanical strength and durability, enabling low-cost and large-scale production. Thus, this work reinforces the understanding of the fundamental research and significantly promotes the practical applications of functional fog-harvesting devices. A bio-inspired fabric with wedge-shaped tracks and patterned wettability was fabricated using knitting technology. 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source Royal Society Of Chemistry Journals 2008-
subjects Biomimetics
Durability
Economic development
Fabrics
Fog
Hydrophobicity
Knitting
Low cost
Mechanical properties
Social security
Technology
Water harvesting
Water transportation
Wettability
title A dual-biomimetic knitted fabric with a manipulable structure and wettability for highly efficient fog harvesting
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